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harmonic_patterns.py
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harmonic_patterns.py
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import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
import mplfinance as mpf
import scipy
from directional_change import directional_change, get_extremes
from dataclasses import dataclass
from typing import Union
from math import log
@dataclass
class XABCD:
XA_AB: Union[float, list, None]
AB_BC: Union[float, list, None]
BC_CD: Union[float, list, None]
XA_AD: Union[float, list, None]
name: str
# Define Patterns
GARTLEY = XABCD(0.618, [0.382, 0.886], [1.13, 1.618], 0.786, "Gartley")
BAT = XABCD([0.382, 0.50], [0.382, 0.886], [1.618, 2.618], 0.886, "Bat")
#ALT_BAT = XABCD(0.382, [0.382, 0.886], [2.0, 3.618], 1.13, "Alt Bat")
BUTTERFLY = XABCD(0.786, [0.382, 0.886], [1.618, 2.24], [1.27, 1.41], "Butterfly")
CRAB = XABCD([0.382, 0.618], [0.382, 0.886], [2.618, 3.618], 1.618, "Crab")
DEEP_CRAB = XABCD(0.886, [0.382, 0.886], [2.0, 3.618], 1.618, "Deep Crab")
CYPHER = XABCD([0.382, 0.618], [1.13, 1.41], [1.27, 2.00], 0.786, "Cypher")
SHARK = XABCD(None, [1.13, 1.618], [1.618, 2.24], [0.886, 1.13], "Shark")
ALL_PATTERNS = [GARTLEY, BAT, BUTTERFLY, CRAB, DEEP_CRAB, CYPHER, SHARK]
@dataclass
class XABCDFound:
X: int
A: int
B: int
C: int
D: int # Index of last point in pattern, the entry is on the close of D
error: float # Error found
name: str
bull: bool
def plot_pattern(ohlc: pd.DataFrame, pat: XABCDFound, pad=3):
idx = ohlc.index
data = ohlc.iloc[pat.X - pad: pat.D + 1 + pad]
plt.style.use('dark_background')
fig = plt.gcf()
ax = fig.gca()
if pat.bull:
s1 = ohlc['low'].to_numpy()
s2 = ohlc['high'].to_numpy()
else:
s2 = ohlc['low'].to_numpy()
s1 = ohlc['high'].to_numpy()
l0 = [(idx[pat.X], s1[pat.X]), (idx[pat.A], s2[pat.A])]
l1 = [(idx[pat.A], s2[pat.A]), (idx[pat.B], s1[pat.B])]
l2 = [(idx[pat.B], s1[pat.B]), (idx[pat.C], s2[pat.C])]
l3 = [(idx[pat.C], s2[pat.C]), (idx[pat.D], s1[pat.D])]
# Connecting lines
l4 = [(idx[pat.A], s2[pat.A]), (idx[pat.C], s2[pat.C])]
l5 = [(idx[pat.B], s1[pat.B]), (idx[pat.D], s1[pat.D])]
l6 = [(idx[pat.X], s1[pat.X]), (idx[pat.B], s1[pat.B])]
l7 = [(idx[pat.X], s1[pat.X]), (idx[pat.D], s1[pat.D])]
mpf.plot(
data,
alines=dict(alines=[l0, l1, l2, l3, l4, l5, l6, l7 ], colors=['w', 'w', 'w', 'w', 'b', 'b', 'b', 'b']),
type='candle', style='charles', ax=ax
)
# Text
xa_ab = abs(s2[pat.A] - s1[pat.B]) / abs(s1[pat.X] - s2[pat.A])
ab_bc = abs(s1[pat.B] - s2[pat.C]) / abs(s2[pat.A] - s1[pat.B])
bc_cd = abs(s2[pat.C] - s1[pat.D]) / abs(s1[pat.B] - s2[pat.C])
xa_ad = abs(s2[pat.A] - s1[pat.D]) / abs(s1[pat.X] - s2[pat.A])
ax.text(int((pat.X + pat.B) / 2) - pat.X + pad, (s1[pat.X] + s1[pat.B]) / 2 , str(round(xa_ab, 3)), color='orange', fontsize='x-large')
ax.text(int((pat.A + pat.C) / 2) - pat.X + pad, (s2[pat.A] + s2[pat.C]) / 2 , str(round(ab_bc, 3)), color='orange', fontsize='x-large')
ax.text(int((pat.B + pat.D) / 2) - pat.X + pad, (s1[pat.B] + s1[pat.D]) / 2 , str(round(bc_cd, 3)), color='orange', fontsize='x-large')
ax.text(int((pat.X + pat.D) / 2) - pat.X + pad, (s1[pat.X] + s1[pat.D]) / 2 , str(round(xa_ad, 3)), color='orange', fontsize='x-large')
desc_string = pat.name
desc_string += "\nError: " + str(round(pat.error , 5))
if pat.bull:
plt_price = data['high'].max() - 0.05 * (data['high'].max() - data['low'].min())
else:
plt_price = data['low'].min() + 0.05 * (data['high'].max() - data['low'].min())
ax.text(0, plt_price , desc_string, color='yellow', fontsize='x-large')
plt.show()
def get_error(actual_ratio: float, pattern_ratio: Union[float, list, None]):
if pattern_ratio is None: # No requirement (Shark)
return 0.0
log_actual = log(actual_ratio)
if isinstance(pattern_ratio, list): # Acceptable range
log_pat0 = log(pattern_ratio[0])
log_pat1 = log(pattern_ratio[1])
assert(log_pat1 > log_pat0)
if log_pat0 <= log_actual <= log_pat1:
return 0.0
#else:
# return 1e20
err = min( abs(log_actual - log_pat0), abs(log_actual - log_pat1) )
range_mult = 2.0 # Since range is already more lenient, punish harder.
err *= range_mult
return err
elif isinstance(pattern_ratio, float):
err = abs(log_actual - log(pattern_ratio))
return err
else:
raise TypeError("Invalid pattern ratio type")
def find_xabcd(ohlc: pd.DataFrame, extremes: pd.DataFrame, err_thresh: float = 0.2):
extremes['seg_height'] = (extremes['ext_p'] - extremes['ext_p'].shift(1)).abs()
extremes['retrace_ratio'] = extremes['seg_height'] / extremes['seg_height'].shift(1)
output = {}
for pat in ALL_PATTERNS:
pat_data = {}
pat_data['bull_signal'] = np.zeros(len(ohlc))
pat_data['bull_patterns'] = []
pat_data['bear_signal'] = np.zeros(len(ohlc))
pat_data['bear_patterns'] = []
output[pat.name] = pat_data
first_conf = extremes.index[0]
extreme_i = 0
entry_taken = 0
pattern_used = None
for i in range(first_conf, len(ohlc)):
if extremes.index[extreme_i + 1] == i:
entry_taken = 0
extreme_i += 1
if entry_taken != 0:
if entry_taken == 1:
output[pattern_used]['bull_signal'][i] = 1
else:
output[pattern_used]['bear_signal'][i] = -1
continue
if extreme_i + 1 >= len(extremes):
break
if extreme_i < 3:
continue
ext_type = extremes.iloc[extreme_i]['type']
last_conf_i = extremes.index[extreme_i]
if extremes.iloc[extreme_i]['type'] > 0.0:
# Last extreme was a top, meaning we're on a leg down currently.
# We are checking for bull patterns
D_price = ohlc.iloc[i]['low']
# Check that the current low is the lowest since last confirmed top
if ohlc.iloc[last_conf_i:i]['low'].min() < D_price:
continue
else:
# Last extreme was a bottom, meaning we're on a leg up currently.
# We are checking for bear patterns
D_price = ohlc.iloc[i]['high']
# Check that the current high is the highest since last confirmed bottom
if ohlc.iloc[last_conf_i:i]['high'].max() > D_price:
continue
# D_Price set, get ratios
dc_retrace = abs(D_price - extremes.iloc[extreme_i]['ext_p']) / extremes.iloc[extreme_i]['seg_height']
xa_ad_retrace = abs(D_price - extremes.iloc[extreme_i - 2]['ext_p']) / extremes.iloc[extreme_i - 2]['seg_height']
best_err = 1e30
best_pat = None
for pat in ALL_PATTERNS:
err = 0.0
err += get_error(extremes.iloc[extreme_i]['retrace_ratio'], pat.AB_BC)
err += get_error(extremes.iloc[extreme_i - 1]['retrace_ratio'], pat.XA_AB)
err += get_error(dc_retrace, pat.BC_CD)
err += get_error(xa_ad_retrace, pat.XA_AD)
if err < best_err:
best_err = err
best_pat = pat.name
if best_err <= err_thresh:
pattern_data = XABCDFound(
int(extremes.iloc[extreme_i - 3]['ext_i']),
int(extremes.iloc[extreme_i - 2]['ext_i']),
int(extremes.iloc[extreme_i - 1]['ext_i']),
int(extremes.iloc[extreme_i]['ext_i']),
i,
best_err, best_pat, True
)
pattern_used = best_pat
if ext_type > 0.0:
entry_taken = 1
pattern_data.name = "Bull" + pattern_data.name
pattern_data.bull = True
output[pattern_used]['bull_signal'][i] = 1
output[pattern_used]['bull_patterns'].append(pattern_data)
else:
entry_taken = -1
pattern_data.name = "Bear" + pattern_data.name
pattern_data.bull = False
output[pattern_used]['bear_signal'][i] = -1
output[pattern_used]['bear_patterns'].append(pattern_data)
return output
if __name__ == '__main__':
data = pd.read_csv('BTCUSDT3600.csv')
data['date'] = data['date'].astype('datetime64[s]')
data = data.set_index('date')
#data = data[data.index < '2019-01-01']
# This takes a while to run fyi
data['r'] = np.log(data['close']).diff().shift(-1)
all_combined = np.zeros(len(data))
sigmas = [0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04]
for sigma in sigmas:
extremes = get_extremes(data, sigma)
output = find_xabcd(data, extremes, 0.5)
sig = np.zeros(len(data))
for pat in ALL_PATTERNS:
sig += output[pat.name]['bear_signal'] + output[pat.name]['bull_signal']
all_combined += sig
print("done", sigma)
all_combined /= len(sigmas)
data['combined_signal'] = all_combined
data['combined_returns'] = data['r'] * data['combined_signal']
win_returns = data[data['combined_returns'] > 0]['combined_returns'].sum()
lose_returns = data[data['combined_returns'] < 0]['combined_returns'].abs().sum()
combined_pf = win_returns / lose_returns
print("Combined PF", combined_pf)
'''
# Test single set of parameters
extremes = get_extremes(data, 0.02)
output = find_xabcd(data, extremes, 0.2)
sig = np.zeros(len(data))
for pat in ALL_PATTERNS:
sig += output[pat.name]['bear_signal'] + output[pat.name]['bull_signal']
data['r'] = np.log(data['close']).diff().shift(-1)
data['signal_return'] = data['r'] * sig # Returns of all patterns combined
plt.style.use('dark_background')
data['signal_return'].cumsum().plot()
'''
'''
# Test several sigma vvalues
data['r'] = np.log(data['close']).diff().shift(-1)
plt.style.use('dark_background')
for sigma in [0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04]:
extremes = get_extremes(data, sigma)
output = find_xabcd(data, extremes, 0.2)
sig = np.zeros(len(data))
for pat in ALL_PATTERNS:
sig += output[pat.name]['bear_signal'] + output[pat.name]['bull_signal']
data['signal_return'] = data['r'] * sig # Returns of all patterns combined
data['signal_return'].cumsum().plot(label=str(sigma))
pf = data[data['signal_return'] > 0]['signal_return'].sum() / data[data['signal_return'] < 0]['signal_return'].abs().sum()
print(sigma, "Profit Factor: ", pf)
plt.legend(prop={'size': 16})
plt.show()
'''
'''
# Render error graph
all_pfs = []
all_thresholds = [0.1, 0.15, 0.2, 0.25, 0.3, 0.35, 0.4, 0.45, 0.5, 0.55, 0.65, 0.7, 0.75]
#all_thresholds = [0.1, 0.15]
for threshold in all_thresholds:
all_combined = np.zeros(len(data))
sigmas = [0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04]
for sigma in sigmas:
extremes = get_extremes(data, sigma)
output = find_xabcd(data, extremes, threshold)
sig = np.zeros(len(data))
for pat in ALL_PATTERNS:
sig += output[pat.name]['bear_signal'] + output[pat.name]['bull_signal']
all_combined += sig
all_combined /= len(sigmas)
data['combined_signal'] = all_combined
data['combined_returns'] = data['r'] * data['combined_signal']
win_returns = data[data['combined_returns'] > 0]['combined_returns'].sum()
lose_returns = data[data['combined_returns'] < 0]['combined_returns'].abs().sum()
combined_pf = win_returns / lose_returns
all_pfs.append(combined_pf)
plt.style.use('dark_background')
err_thresh_pfs = pd.Series(all_pfs, index=all_thresholds)
err_thresh_pfs.plot()
plt.axhline(1.0, color='white')
plt.show()
'''
'''
# Find best err pattern
best_pat = None
best_err = 1000
for pat in output['Gartley']['bull_patterns']:
if pat.error < best_err:
best_err = pat.error
best_pat = pat
'''
'''
#Bar Charts by pattern PF and count
sigmas = []
patterns = []
pfs = []
counts = []
#for sigma in [0.01, 0.02, 0.03, 0.04]:
for sigma in [0.01, 0.015, 0.02, 0.025, 0.03, 0.035, 0.04]:
extremes = get_extremes(data, sigma)
output = find_xabcd(data, extremes, 0.2)
for pat in ALL_PATTERNS:
sig = output[pat.name]['bear_signal'] + output[pat.name]['bull_signal']
count = len(output[pat.name]['bear_patterns']) + len(output[pat.name]['bull_patterns'])
rets = (data['r'] * sig)
pf = rets[rets > 0].sum() / rets[rets < 0].abs().sum()
if np.isnan(pf): # Set nan value to a neutral 1.0 for profit factor
pf = 1.0
if pf > 4.0: # put a ceil at 4, as that high of PF is from low sample size. Makes graph look better
pf = 4.0
sigmas.append(sigma)
patterns.append(pat.name)
pfs.append(pf)
counts.append(count)
import seaborn as sns
df = pd.DataFrame()
df['sigmas'] = sigmas
df['Patterns'] = patterns
df['Profit Factor'] = pfs
df['Count'] = counts
plt.style.use('dark_background')
sns.catplot(
data=df, y="Patterns", x='Profit Factor', hue="sigmas", kind='bar',
palette="dark", edgecolor=".6", legend=False
)
plt.axvline(1.0, color='white')
plt.legend(prop={'size': 16}, title='Sigma Values')
plt.show()
sns.catplot(
data=df, y="Patterns", x='Count', hue="sigmas", kind='bar',
palette="dark", edgecolor=".6", legend=False
)
plt.legend(prop={'size': 16}, title='Sigma Values')
plt.show()
'''