Files
catalyst/zipline/optimize/example.py
T
2012-10-08 17:32:41 -04:00

175 lines
5.1 KiB
Python

#
# Copyright 2012 Quantopian, Inc.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# WARNING: This file is still work in progress and contains rather
# random code snippets.
import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
from zipline.gens.mavg import MovingAverage
from zipline.algorithm import TradingAlgorithm
class DMA(TradingAlgorithm):
"""Dual Moving Average algorithm.
"""
def initialize(self, amount=100, short_window=20, long_window=40):
self.amount = amount
self.events = 0
self.invested = {}
for sid in self.sids:
self.invested[sid] = False
self.add_transform(MovingAverage, 'short_mavg', ['price'],
market_aware=True,
days=short_window)
self.add_transform(MovingAverage, 'long_mavg', ['price'],
market_aware=True,
days=long_window)
def handle_data(self, data):
self.events += 1
for sid in self.sids:
# access transforms via their user-defined tag
if (data[sid].short_mavg['price'] >
data[sid].long_mavg['price']) \
and not self.invested[sid]:
self.order(sid, self.amount)
self.invested[sid] = True
elif (data[sid].short_mavg['price'] <
data[sid].long_mavg['price']) \
and self.invested[sid]:
self.order(sid, -self.amount)
self.invested[sid] = False
def load_close_px(indexes=None, stocks=None):
from pandas.io.data import DataReader
import pytz
from collections import OrderedDict
if indexes is None:
indexes = {'SPX': '^GSPC'}
if stocks is None:
stocks = ['AAPL', 'GE', 'IBM', 'MSFT', 'XOM', 'AA', 'JNJ', 'PEP']
start = pd.datetime(1990, 1, 1, 0, 0, 0, 0, pytz.utc)
end = pd.datetime(1992, 1, 1, 0, 0, 0, 0, pytz.utc)
data = OrderedDict()
for stock in stocks:
print stock
stkd = DataReader(stock, 'yahoo', start, end).sort_index()
data[stock] = stkd
for name, ticker in indexes.iteritems():
print name
stkd = DataReader(ticker, 'yahoo', start, end).sort_index()
data[name] = stkd
#df = pd.DataFrame({key: d['Close'] for key, d in data.iteritems()})
df = pd.DataFrame({i: d['Close'] for i, d in enumerate(data.itervalues())})
df.index = df.index.tz_localize(pytz.utc)
df.save('close_px.dat')
return df
def run((short_window, long_window)):
data = pd.load('close_px.dat')
#data = load_close_px()
myalgo = DMA([0, 1],
amount=100,
short_window=short_window,
long_window=long_window)
stats = myalgo.run(data)
stats['sw'] = short_window
stats['lw'] = long_window
return stats
def explore_params():
sws, lws = np.mgrid[10:20:5, 10:20:5]
stats_all = map(run, zip(sws.flatten(), lws.flatten()))
stats = pd.concat(stats_all)
returns = stats.groupby(['sw', 'lw']).sum()
plt.contourf(sws, lws, returns.returns.reshape(sws.shape))
plt.xlabel('Short window length')
plt.ylabel('Long window length')
plt.savefig('DMA_contour.png')
plt.show()
def get_opt_holdings_qp(univ_rets, track_rets):
from cvxopt import matrix
from cvxopt.solvers import qp
# set up the QP for CVXOPT
# .5 x' P x + q'x
# P = 2 * R'R
# q = - 2 * bmk'R
R = univ_rets.values
b = track_rets.values
P = matrix(2 * np.dot(R.T, R))
q = matrix(-2 * np.dot(R.T, b))
result = qp(P, q)
if result['status'] != 'optimal':
raise Exception('optimum not reached by QP')
return pd.Series(np.array(result['x']).ravel(), index=univ_rets.columns)
def opt_portfolio(cov, budget, min_return):
from cvxopt import matrix
from cvxopt.solvers import qp
n = len(cov)
cov = matrix(2 * cov)
q = matrix(np.zeros(n))
h = matrix(budget) # G*x < h
# coneqp
result = qp(cov, q, h=h)
if result['status'] != 'optimal':
raise Exception('optimum not reached by QP')
return pd.Series(np.array(result['x']).ravel())
def calc_te(weights, univ_rets, track_rets):
port_rets = (univ_rets * weights).sum(1)
return (port_rets - track_rets).std()
def plot_returns(port_returns, bmk_returns):
plt.figure()
cum_port = ((1 + port_returns).cumprod() - 1)
cum_bmk = ((1 + bmk_returns).cumprod() - 1)
# cum_port = port_returns.cumsum()
# cum_bmk = bmk_returns.cumsum()
cum_port.plot(label='Portfolio returns')
cum_bmk.plot(label='Benchmark')
plt.title('Portfolio performance')
plt.legend(loc='best')
print run((10, 20))