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btwalkforward.py
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btwalkforward.py
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from sklearn.model_selection import TimeSeriesSplit
from sklearn.utils import indexable
from sklearn.utils.validation import _num_samples
import numpy as np
import backtrader as bt
import backtrader.indicators as btind
import datetime as dt
import pandas as pd
import pandas_datareader as web
from pandas import Series, DataFrame
import random
from copy import deepcopy
import optunity.metrics
import backtrader.analyzers as btanal
'''
- Currently (last two period is training set for next period, but I want the total to be validated on every single period) --> switch!
- strategy should be easy to replace
- implement daily vs. weekly etc. compression)
- improve the sizer (depending on the strategy)
- Implement number of trades (greater than 50 + # var * 50 is suggested by the author (I assume this is meant for daily values) & volatility of trade returns for testing and training to indicate the statistical fitness of the model (https://www.tradelikeamachine.com/blog/over-optimization/part-3-in-sample-out-of-sample-trading-system-backtesting integrate )(volatility of trades?) --> self.returnvola = btind.StdDev(btind.PctChange(), period=30)
https://www.tradelikeamachine.com/images/blog/over-optimization/quantitative-out-of-sample-walk-forward-metrics.png
- pyfolio integration
- better charting?
- btreport?
- clean up code?
- find a momentum strategy to implement
- etc.
'''
pd.set_option('display.max_rows', 10)
pd.set_option('display.max_columns', 10)
pd.set_option('display.width', 1000)
globalparams = dict(strategy='long_short', # if a different strategy is used
n_splits=10, # how many chunks the data should have
fixed_length=True, # by setting it False the training data will will grow over time, otherwise it will keep the size given under train_splits
train_splits=1, # how many splits should be used to train the model (be aware of these two variables may not work with your strategy, i.e. SMA100 but two training splits are just 110 days or less than 100 days)
test_splits=1, # how many splits should the data be tested on?
start=dt.datetime(2010, 1, 1),
end=dt.datetime(2020, 1, 31),
symbols=["TQQQ"], #, "GOOG", "MSFT", "AMZN", "SNY", "VZ", "IBM", "HPQ", "QCOM", "NVDA"
cash=10000,
commission=0.02,
coc='True',
num_evals=100, # how often should the optimizer try to optimize
var1range=[1, 1.25], # reasonable range within the optimization should happen (variable 1)
var2range=[1, 1.25], # reasonable range within the optimization should happen (variable 2)
sma_period=15, #SMA Band Period
vola=False, # this should only be used if one has a working strategy: if True the total period will be optimized and then the volatility of the overall parameters can be observed todo implement it
)
class TimeSeriesSplitImproved(TimeSeriesSplit):
"""Time Series cross-validator
Provides train/test indices to split time series data samples
that are observed at fixed time intervals, in train/test sets.
In each split, test indices must be higher than before, and thus shuffling
in cross validator is inappropriate.
This cross-validation object is a variation of :class:`KFold`.
In the kth split, it returns first k folds as train set and the
(k+1)th fold as test set.
Note that unlike standard cross-validation methods, successive
training sets are supersets of those that come before them.
Read more in the :ref:`User Guide `.
Parameters
----------
n_splits : int, default=3
Number of splits. Must be at least 1.
Examples
--------
>>> from sklearn.model_selection import TimeSeriesSplit
>>> X = np.array([[1, 2], [3, 4], [1, 2], [3, 4]])
>>> y = np.array([1, 2, 3, 4])
>>> tscv = TimeSeriesSplit(n_splits=3)
>>> print(tscv) # doctest: +NORMALIZE_WHITESPACE
TimeSeriesSplit(n_splits=3)
>>> for train_index, test_index in tscv.split(X):
... print("TRAIN:", train_index, "TEST:", test_index)
... X_train, X_test = X[train_index], X[test_index]
... y_train, y_test = y[train_index], y[test_index]
TRAIN: [0] TEST: [1]
TRAIN: [0 1] TEST: [2]
TRAIN: [0 1 2] TEST: [3]
>>> for train_index, test_index in tscv.split(X, fixed_length=True):
... print("TRAIN:", train_index, "TEST:", test_index)
... X_train, X_test = X[train_index], X[test_index]
... y_train, y_test = y[train_index], y[test_index]
TRAIN: [0] TEST: [1]
TRAIN: [1] TEST: [2]
TRAIN: [2] TEST: [3]
>>> for train_index, test_index in tscv.split(X, fixed_length=True,
... train_splits=2):
... print("TRAIN:", train_index, "TEST:", test_index)
... X_train, X_test = X[train_index], X[test_index]
... y_train, y_test = y[train_index], y[test_index]
TRAIN: [0 1] TEST: [2]
TRAIN: [1 2] TEST: [3]
Notes
-----
When ``fixed_length`` is ``False``, the training set has size
``i * train_splits * n_samples // (n_splits + 1) + n_samples %
(n_splits + 1)`` in the ``i``th split, with a test set of size
``n_samples//(n_splits + 1) * test_splits``, where ``n_samples``
is the number of samples. If fixed_length is True, replace ``i``
in the above formulation with 1, and ignore ``n_samples %
(n_splits + 1)`` except for the first training set. The number
of test sets is ``n_splits + 2 - train_splits - test_splits``.
"""
def split(self, X, y=None, groups=None, fixed_length=False,
train_splits=1, test_splits=1):
"""Generate indices to split data into training and test set.
Parameters
----------
X : array-like, shape (n_samples, n_features)
Training data, where n_samples is the number of samples
and n_features is the number of features.
y : array-like, shape (n_samples,)
Always ignored, exists for compatibility.
groups : array-like, with shape (n_samples,), optional
Always ignored, exists for compatibility.
fixed_length : bool, hether training sets should always have
common length
train_splits : positive int, for the minimum number of
splits to include in training sets
test_splits : positive int, for the number of splits to
include in the test set
Returns
-------
train : ndarray
The training set indices for that split.
test : ndarray
The testing set indices for that split.
"""
X, y, groups = indexable(X, y, groups)
n_samples = _num_samples(X)
n_splits = self.n_splits
n_folds = n_splits + 1
train_splits, test_splits = int(train_splits), int(test_splits)
if n_folds > n_samples:
raise ValueError(
("Cannot have number of folds ={0} greater"
" than the number of samples: {1}.").format(n_folds,
n_samples))
if ((n_folds - train_splits - test_splits) == 0 and test_splits > 0):
raise ValueError(
("Both train_splits and test_splits must be positive"
" integers."))
indices = np.arange(n_samples)
split_size = (n_samples // n_folds)
test_size = split_size * test_splits
train_size = split_size * train_splits
test_starts = range(train_size + n_samples % n_folds,
n_samples - (test_size - split_size),
split_size)
if fixed_length:
for i, test_start in zip(range(len(test_starts)),
test_starts):
rem = 0
if i == 0:
rem = n_samples % n_folds
yield (indices[(test_start - train_size - rem):test_start],
indices[test_start:test_start + test_size])
else:
for test_start in test_starts:
yield (indices[:test_start],
indices[test_start:test_start + test_size])
class long_short(bt.Strategy):
"""A simple moving average crossover strategy; crossing of a fast and slow moving average generates buy/sell
signals"""
params = dict(var1=20, var2=50) # The windows for both var1 (fast) and var2 (slow) moving averages
def __init__(self):
"""Initialize the strategy"""
self.sma = dict()
self.fastma = dict()
self.slowma = dict()
self.regime = dict()
for d in self.getdatanames():
# The moving averages
self.sma[d] = btind.SMA(self.getdatabyname(d), # The symbol for the moving average
period=globalparams['sma_period'], # Fast moving average
plotname="SMA20: " + d)
def next(self):
"""Define what will be done in a single step, including creating and closing trades"""
for d in self.getdatanames(): # Looping through all symbols
pos = self.getpositionbyname(d).size or 0
if pos == 0: # Are we out of the market?
# Consider the possibility of entrance
# Notice the indexing; [0] always means the present bar, and [-1] the bar immediately preceding
# Thus, the condition below translates to: "If today the regime is bullish (greater than
# 0) and yesterday the regime was not bullish"
if self.sma[d][0] * self.params.var1 > self.getdatabyname(d).high[0]: # A buy signal
self.order_target_percent(data=self.getdatabyname(d), target=0.98)
else: # We have an open position
if self.getdatabyname(d).close[-1] * self.params.var2 <= self.getdatabyname(d).high[0]: # A sell signal
self.order_target_percent(data=self.getdatabyname(d), target=0)
class SMAC(bt.Strategy):
"""A simple moving average crossover strategy; crossing of a fast and slow moving average generates buy/sell
signals"""
params = dict(var1=20, var2=50) # The windows for both var1 (fast) and var2 (slow) moving averages
def __init__(self):
"""Initialize the strategy"""
self.fastma = dict()
self.slowma = dict()
self.regime = dict()
if self.params.var1 > self.params.var2:
vfast = self.params.var1
self.params.var1 = self.params.var2
self.params.var2 = vfast
for d in self.getdatanames():
# The moving averages
self.fastma[d] = btind.SMA(self.getdatabyname(d), # The symbol for the moving average
period=self.params.var1, # Fast moving average
plotname="FastMA: " + d)
self.slowma[d] = btind.SMA(self.getdatabyname(d), # The symbol for the moving average
period=self.params.var2, # Slow moving average
plotname="SlowMA: " + d)
# Get the regime
self.regime[d] = self.fastma[d] - self.slowma[d] # Positive when bullish
def next(self):
"""Define what will be done in a single step, including creating and closing trades"""
for d in self.getdatanames(): # Looping through all symbols
pos = self.getpositionbyname(d).size or 0
if pos == 0: # Are we out of the market?
# Consider the possibility of entrance
# Notice the indexing; [0] always means the present bar, and [-1] the bar immediately preceding
# Thus, the condition below translates to: "If today the regime is bullish (greater than
# 0) and yesterday the regime was not bullish"
if self.regime[d][0] > 0 and self.regime[d][-1] <= 0: # A buy signal
self.buy(data=self.getdatabyname(d))
else: # We have an open position
if self.regime[d][0] <= 0 and self.regime[d][-1] > 0: # A sell signal
self.sell(data=self.getdatabyname(d))
class PropSizer(bt.Sizer): # todo need rework
"""A position sizer that will buy as many stocks as necessary for a certain proportion of the portfolio
to be committed to the position, while allowing stocks to be bought in batches (say, 100)"""
params = {"prop": 0.95, "batch": 100}
def _getsizing(self, comminfo, cash, data, isbuy):
"""Returns the proper sizing"""
if isbuy: # Buying
target = self.broker.getvalue() * self.params.prop # Ideal total value of the position
price = data.close[0]
shares_ideal = target / price # How many shares are needed to get target
batches = int(shares_ideal / self.params.batch) # How many batches is this trade?
shares = batches * self.params.batch # The actual number of shares bought
if shares * price > cash:
return 0 # Not enough money for this trade ????????? Why not buy anything if there is no money?
else:
return shares
else: # Selling
return self.broker.getposition(data).size # Clear the position
class AcctValue(bt.Observer):
alias = ('Value',)
lines = ('value',)
plotinfo = {"plot": True, "subplot": True}
def next(self):
self.lines.value[0] = self._owner.broker.getvalue() # Get today's account value (cash + stocks)
class AcctStats(bt.Analyzer):
"""A simple analyzer that gets the gain in the value of the account; should be self-explanatory"""
def __init__(self):
self.start_val = self.strategy.broker.get_value()
self.end_val = None
def stop(self):
self.end_val = self.strategy.broker.get_value()
def get_analysis(self):
return {"start": self.start_val, "end": self.end_val,
"growth": self.end_val - self.start_val, "return": self.end_val / self.start_val}
# Different stocks from past posts because of different data source (no plot for NTDOY)
datafeeds = {s: web.DataReader(s, "yahoo", globalparams['start'], globalparams['end']) for s in globalparams['symbols']}
#resample to weekly data
for s, df in datafeeds.items():
'''
df['Date'] = pd.to_datetime(df['Date'])
df.set_index('Date', inplace=True)
df.sort_index(inplace=True)
'''
def take_first(array_like):
return array_like[0]
def take_last(array_like):
return array_like[-1]
ohlc_dict= {'High': 'max',
'Low': 'min',
'Open': take_first,
'Close': take_last,
'Adj Close': take_last,
'Volume': 'sum'}
datafeeds[s] = df.resample('W', # Weekly resample
loffset=pd.offsets.timedelta(days=-2)).agg(ohlc_dict).copy() # to put the labels to Monday
for df in datafeeds.values():
df["OpenInterest"] = 0 # PandasData reader expects an OpenInterest column;
tscv = TimeSeriesSplitImproved(globalparams['n_splits'])
split = tscv.split(datafeeds[globalparams['symbols'][0]], fixed_length=globalparams['fixed_length'], train_splits=globalparams['train_splits'], test_splits=globalparams['test_splits'])
walk_forward_results = list()
# Be prepared: this will take a while
for train, test in split:
# TRAINING
# Optimize with optunity
def runstrat(var1, var2):
cerebro = bt.Cerebro(stdstats=False, maxcpus=None)
cerebro.addstrategy(eval(globalparams['strategy']), var1=var1, var2=var2) # toDO make the float int choice switchable
cerebro.broker.setcash(globalparams['cash'])
cerebro.broker.setcommission(globalparams['commission'])
for s, df in datafeeds.items():
data = bt.feeds.PandasData(dataname=df.iloc[train], name=s) # Add a subset of data
# to the object that
# corresponds to training
cerebro.adddata(data)
cerebro.broker.set_coc(eval(globalparams['coc']))
cerebro.run()
return cerebro.broker.getvalue() # ToDo make the variable that should be optimized flexible
opt = optunity.maximize(runstrat, num_evals=globalparams['num_evals'], var1=globalparams['var1range'], var2=globalparams['var2range'])
optimal_pars, details, _ = opt
tester = bt.Cerebro(stdstats=False, maxcpus=None)
tester.broker.set_cash(globalparams['cash'])
tester.broker.set_coc(eval(globalparams['coc']))
tester.broker.setcommission(globalparams['commission'])
tester.addanalyzer(AcctStats)
tester.addsizer(PropSizer)
tester.addanalyzer(bt.analyzers.SharpeRatio, riskfreerate=0.0)
# TESTING
tester.addstrategy(eval(globalparams['strategy']), var1=optimal_pars['var1'],
var2=optimal_pars['var2']) # Test with optimal combination toDO like above int vs float
for s, df in datafeeds.items():
data = bt.feeds.PandasData(dataname=df.iloc[test], name=s) # Add a subset of data
# to the object that
# corresponds to testing
tester.adddata(data)
res = tester.run()
res_dict = res[0].analyzers.acctstats.get_analysis()
res_dict["var1"] = optimal_pars['var1']
res_dict["var2"] = optimal_pars['var2']
res_dict["sharpe"] = res[0].analyzers.sharperatio.get_analysis()['sharperatio']
res_dict["start_date"] = datafeeds[globalparams['symbols'][0]].iloc[test[0]].name
res_dict["end_date"] = datafeeds[globalparams['symbols'][0]].iloc[test[-1]].name
walk_forward_results.append(res_dict)
wfdf = DataFrame(walk_forward_results)
print(wfdf.loc[:, wfdf.columns != 'start'])
class SMACWalkForward(bt.Strategy):
"""The SMAC strategy but in a walk-forward analysis context"""
params = {"start_dates": None, # Starting days for trading periods (a list)
"end_dates": None, # Ending day for trading periods (a list)
"var1": None, # List of fast moving average windows, corresponding to start dates (a list)
"var2": None} # Like fast, but for slow moving average window (a list)
# All the above lists must be of the same length, and they all line up
def __init__(self):
"""Initialize the strategy"""
self.sma = dict()
self.var1 = dict()
self.var2 = dict()
self.regime = dict()
self.date_combos = [c for c in zip(self.p.start_dates, self.p.end_dates)]
'''
# Error checking
if type(self.p.start_dates) is not list or type(self.p.end_dates) is not list or \
type(self.p.fast) is not list or type(self.p.slow) is not list:
raise ValueError("Must past lists filled with numbers to params start_dates, end_dates, fast, slow.")
elif len(self.p.start_dates) != len(self.p.end_dates) or \
len(self.p.fast) != len(self.p.start_dates) or len(self.p.slow) != len(self.p.start_dates):
raise ValueError("All lists passed to params must have same length.")
'''
for d in self.getdatanames():
self.sma[d] = dict()
self.var1[d] = dict()
self.var2[d] = dict()
self.regime[d] = dict()
# Additional indexing, allowing for differing start/end dates
for sd, ed, f, s in zip(self.p.start_dates, self.p.end_dates, self.p.var1, self.p.var2):
# More error checking
'''
if type(f) is not int or type(s) is not int:
raise ValueError("Must include only integers in fast, slow.")
elif f > s:
raise ValueError("Elements in fast cannot exceed elements in slow.")
elif f <= 0 or s <= 0:
raise ValueError("Moving average windows must be positive.")
if type(sd) is not dt.date or type(ed) is not dt.date:
raise ValueError("Only datetime dates allowed in start_dates, end_dates.")
elif ed - sd < dt.timedelta(0):
raise ValueError("Start dates must always be before end dates.")
'''
# The moving averages
# Notice that different moving averages are obtained for different combinations of
# start/end dates
self.sma[d][(sd, ed)] = btind.SimpleMovingAverage(self.getdatabyname(d),
period=globalparams['sma_period'],
plot=False)
self.var1[d][(sd, ed)] = f
self.var2[d][(sd, ed)] = s
'''
self.fastma[d][(sd, ed)] = btind.SimpleMovingAverage(self.getdatabyname(d),
period=f,
plot=False)
self.slowma[d][(sd, ed)] = btind.SimpleMovingAverage(self.getdatabyname(d),
period=s,
plot=False)
# Get the regime
self.regime[d][(sd, ed)] = self.fastma[d][(sd, ed)] - self.slowma[d][(sd, ed)]
# In the future, use the backtrader indicator btind.CrossOver()
'''
def next(self):
"""Define what will be done in a single step, including creating and closing trades"""
# Determine which set of moving averages to use
curdate = self.datetime.date(0)
dtidx = None # Will be index
# Determine which period (if any) we are in
for sd, ed in self.date_combos:
# Debug output
# print('{}: {} < {}: {}, {} < {}: {}'.format(
# len(self), sd, curdate, (sd <= curdate), curdate, ed, (curdate <= ed)))
if sd <= curdate and curdate <= ed:
dtidx = (sd, ed)
# Debug output
# print('{}: the dtixdx is {}, and curdate is {};'.format(len(self), dtidx, curdate))
for d in self.getdatanames(): # Looping through all symbols
pos = self.getpositionbyname(d).size or 0
if dtidx is None: # Not in any window
break # Don't engage in trades
if pos == 0: # Are we out of the market?
# Consider the possibility of entrance
# Notice the indexing; [0] always mens the present bar, and [-1] the bar immediately preceding
# Thus, the condition below translates to: "If today the regime is bullish (greater than
# 0) and yesterday the regime was not bullish"
'''if self.slowma[d][dtidx][0] > self.getdatabyname(d).close[0]: # A buy signal
self.sell(data=self.getdatabyname(d), size=1000)
else: # We have an open position
if self.fastma[d][dtidx][0] < self.getdatabyname(d).close[0]: # A sell signal
self.close(data=self.getdatabyname(d), size=1000)
'''
if self.sma[d][dtidx][0] * self.var1[d][dtidx] > self.getdatabyname(d).high[0]: # A buy signal
self.order_target_percent(data=self.getdatabyname(d), target=0.98)
else: # We have an open position
if self.getdatabyname(d).close[-1] * self.var2[d][dtidx] <= self.getdatabyname(d).high[0]: # A sell signal
self.order_target_percent(data=self.getdatabyname(d), target=0)
cerebro_wf = bt.Cerebro(stdstats=False, maxcpus=None)
plot_symbols = globalparams['symbols']
is_first = True
# plot_symbols = []
for s, df in datafeeds.items():
data = bt.feeds.PandasData(dataname=df, name=s)
if s in plot_symbols:
if is_first:
data_main_plot = data
is_first = False
else:
data.plotinfo.plotmaster = data_main_plot
else:
data.plotinfo.plot = True
cerebro_wf.adddata(data) # Give the data to cerebro
cerebro_wf.broker.setcash(globalparams['cash'])
cerebro_wf.broker.setcommission(globalparams['commission'])
cerebro_wf.broker.set_coc(eval(globalparams['coc']))
cerebro_wf.addstrategy(SMACWalkForward,
# Give the results of the above optimization to SMACWalkForward (NOT OPTIONAL)
var1=[f for f in wfdf.var1],
var2=[s for s in wfdf.var2],
start_dates=[sd.date() for sd in wfdf.start_date],
end_dates=[ed.date() for ed in wfdf.end_date])
cerebro_wf.addobserver(AcctValue)
cerebro_wf.addobservermulti(bt.observers.BuySell) # Plots up/down arrows
cerebro_wf.addsizer(PropSizer)
cerebro_wf.addanalyzer(AcctStats)
cerebro_wf.addanalyzer(bt.analyzers.SharpeRatio, riskfreerate=0.0)
results = cerebro_wf.run()
print(f"Sharpe: {results[0].analyzers.sharperatio.get_analysis()['sharperatio']:.3f}")
cerebro_wf.plot(iplot=True)