Files
catalyst/zipline/utils/factory.py
T
2013-10-01 14:09:26 -04:00

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Python

#
# Copyright 2013 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.
"""
Factory functions to prepare useful data.
"""
import pytz
import random
from collections import OrderedDict
from delorean import Delorean
import pandas as pd
import numpy as np
from datetime import datetime, timedelta
from zipline.protocol import DailyReturn, Event, DATASOURCE_TYPE
from zipline.sources import (SpecificEquityTrades,
DataFrameSource,
DataPanelSource)
from zipline.finance.trading import SimulationParameters
import zipline.finance.trading as trading
from zipline.sources.test_source import (
date_gen,
create_trade
)
# For backwards compatibility
from zipline.data.loader import (load_from_yahoo,
load_bars_from_yahoo)
__all__ = ['load_from_yahoo', 'load_bars_from_yahoo']
def create_simulation_parameters(year=2006, start=None, end=None,
capital_base=float("1.0e5"),
num_days=None
):
"""Construct a complete environment with reasonable defaults"""
if start is None:
start = datetime(year, 1, 1, tzinfo=pytz.utc)
if end is None:
if num_days:
trading.environment = trading.TradingEnvironment()
start_index = trading.environment.trading_days.searchsorted(
start)
end = trading.environment.trading_days[start_index + num_days - 1]
else:
end = datetime(year, 12, 31, tzinfo=pytz.utc)
sim_params = SimulationParameters(
period_start=start,
period_end=end,
capital_base=capital_base,
)
return sim_params
def create_noop_environment():
oneday = timedelta(days=1)
start = datetime(2006, 1, 1, tzinfo=pytz.utc)
bm_returns = []
tr_curves = OrderedDict()
for day in date_gen(start=start, delta=oneday, count=252):
dr = DailyReturn(day, 0.01)
bm_returns.append(dr)
curve = {
'10year': 0.0799,
'1month': 0.0799,
'1year': 0.0785,
'20year': 0.0765,
'2year': 0.0794,
'30year': 0.0804,
'3month': 0.0789,
'3year': 0.0796,
'5year': 0.0792,
'6month': 0.0794,
'7year': 0.0804,
'tid': 1752
}
tr_curves[day] = curve
load_nodata = lambda x: (bm_returns, tr_curves)
return trading.TradingEnvironment(load=load_nodata)
def create_random_simulation_parameters():
trading.environment = trading.TradingEnvironment()
treasury_curves = trading.environment.treasury_curves
for n in range(100):
random_index = random.randint(
0,
len(treasury_curves) - 1
)
start_dt = treasury_curves.index[random_index]
end_dt = start_dt + timedelta(days=365)
now = datetime.utcnow().replace(tzinfo=pytz.utc)
if end_dt <= now:
break
assert end_dt <= now, """
failed to find a suitable daterange after 100 attempts. please double
check treasury and benchmark data in findb, and re-run the test."""
sim_params = SimulationParameters(
period_start=start_dt,
period_end=end_dt
)
return sim_params, start_dt, end_dt
def get_next_trading_dt(current, interval):
naive = current.replace(tzinfo=None)
delo = Delorean(naive, pytz.utc.zone)
ex_tz = trading.environment.exchange_tz
next_dt = delo.shift(ex_tz).datetime
while True:
next_dt = next_dt + interval
next_delo = Delorean(next_dt.replace(tzinfo=None), ex_tz)
next_utc = next_delo.shift(pytz.utc.zone).datetime
if trading.environment.is_market_hours(next_utc):
break
return next_utc
def create_trade_history(sid, prices, amounts, interval, sim_params,
source_id="test_factory"):
trades = []
current = sim_params.first_open
oneday = timedelta(days=1)
use_midnight = interval >= oneday
for price, amount in zip(prices, amounts):
if use_midnight:
trade_dt = current.replace(hour=0, minute=0)
else:
trade_dt = current
trade = create_trade(sid, price, amount, trade_dt, source_id)
trades.append(trade)
current = get_next_trading_dt(current, interval)
assert len(trades) == len(prices)
return trades
def create_dividend(sid, payment, declared_date, ex_date, pay_date):
div = Event({
'sid': sid,
'gross_amount': payment,
'net_amount': payment,
'dt': declared_date.replace(hour=0, minute=0, second=0, microsecond=0),
'ex_date': ex_date.replace(hour=0, minute=0, second=0, microsecond=0),
'pay_date': pay_date.replace(hour=0, minute=0, second=0,
microsecond=0),
'type': DATASOURCE_TYPE.DIVIDEND
})
return div
def create_split(sid, ratio, date):
return Event({
'sid': sid,
'ratio': ratio,
'dt': date.replace(hour=0, minute=0, second=0, microsecond=0),
'type': DATASOURCE_TYPE.SPLIT
})
def create_txn(sid, price, amount, datetime):
txn = Event({
'sid': sid,
'amount': amount,
'dt': datetime,
'price': price,
'type': DATASOURCE_TYPE.TRANSACTION
})
return txn
def create_commission(sid, value, datetime):
txn = Event({
'dt': datetime,
'type': DATASOURCE_TYPE.COMMISSION,
'cost': value,
'sid': sid
})
return txn
def create_txn_history(sid, priceList, amtList, interval, sim_params):
txns = []
current = sim_params.first_open
for price, amount in zip(priceList, amtList):
current = get_next_trading_dt(current, interval)
txns.append(create_txn(sid, price, amount, current))
current = current + interval
return txns
def create_returns_from_range(sim_params):
current = sim_params.first_open
end = sim_params.last_close
test_range = []
while current <= end:
r = DailyReturn(current, random.random())
test_range.append(r)
current = trading.environment.next_trading_day(current)
return test_range
def create_returns_from_list(returns, sim_params):
current = sim_params.first_open
test_range = []
# sometimes the range starts with a non-trading day.
if not trading.environment.is_trading_day(current):
current = trading.environment.next_trading_day(current)
for return_val in returns:
r = DailyReturn(current, return_val)
test_range.append(r)
current = trading.environment.next_trading_day(current)
return test_range
def create_daily_trade_source(sids, trade_count, sim_params,
concurrent=False):
"""
creates trade_count trades for each sid in sids list.
first trade will be on sim_params.period_start, and daily
thereafter for each sid. Thus, two sids should result in two trades per
day.
Important side-effect: sim_params.period_end will be modified
to match the day of the final trade.
"""
return create_trade_source(
sids,
trade_count,
timedelta(days=1),
sim_params,
concurrent=concurrent
)
def create_minutely_trade_source(sids, trade_count, sim_params,
concurrent=False):
"""
creates trade_count trades for each sid in sids list.
first trade will be on sim_params.period_start, and every minute
thereafter for each sid. Thus, two sids should result in two trades per
minute.
Important side-effect: sim_params.period_end will be modified
to match the day of the final trade.
"""
return create_trade_source(
sids,
trade_count,
timedelta(minutes=1),
sim_params,
concurrent=concurrent
)
def create_trade_source(sids, trade_count,
trade_time_increment, sim_params,
concurrent=False):
args = tuple()
kwargs = {
'count': trade_count,
'sids': sids,
'start': sim_params.first_open,
'delta': trade_time_increment,
'filter': sids,
'concurrent': concurrent
}
source = SpecificEquityTrades(*args, **kwargs)
# TODO: do we need to set the trading environment's end to same dt as
# the last trade in the history?
# sim_params.period_end = trade_history[-1].dt
return source
def create_test_df_source(sim_params=None, bars='daily'):
if bars == 'daily':
freq = pd.datetools.BDay()
elif bars == 'minute':
freq = pd.datetools.Minute()
else:
raise ValueError('%s bars not understood.' % freq)
if sim_params:
index = sim_params.trading_days
else:
start = pd.datetime(1990, 1, 3, 0, 0, 0, 0, pytz.utc)
end = pd.datetime(1990, 1, 8, 0, 0, 0, 0, pytz.utc)
index = pd.DatetimeIndex(
start=start,
end=end,
freq=freq
)
if bars == 'minute':
new_index = []
for i in index:
market_open = i.replace(hour=14,
minute=31)
market_close = i.replace(hour=21,
minute=0)
if i >= market_open and i <= market_close:
new_index.append(i)
index = new_index
x = np.arange(1, len(index) + 1)
df = pd.DataFrame(x, index=index, columns=[0])
return DataFrameSource(df), df
def create_test_panel_source(sim_params=None):
start = sim_params.first_open \
if sim_params else pd.datetime(1990, 1, 3, 0, 0, 0, 0, pytz.utc)
end = sim_params.last_close \
if sim_params else pd.datetime(1990, 1, 8, 0, 0, 0, 0, pytz.utc)
index = pd.DatetimeIndex(start=start, end=end, freq=pd.datetools.day)
price = np.arange(0, len(index))
volume = np.ones(len(index)) * 1000
arbitrary = np.ones(len(index))
df = pd.DataFrame({'price': price,
'volume': volume,
'arbitrary': arbitrary},
index=index)
panel = pd.Panel.from_dict({0: df})
return DataPanelSource(panel), panel
def create_test_panel_ohlc_source(sim_params=None):
start = sim_params.first_open \
if sim_params else pd.datetime(1990, 1, 3, 0, 0, 0, 0, pytz.utc)
end = sim_params.last_close \
if sim_params else pd.datetime(1990, 1, 8, 0, 0, 0, 0, pytz.utc)
index = pd.DatetimeIndex(start=start, end=end, freq=pd.datetools.day)
price = np.arange(0, len(index)) + 100
high = price * 1.05
low = price * 0.95
open_ = price + .1 * (price % 2 - .5)
volume = np.ones(len(index)) * 1000
arbitrary = np.ones(len(index))
df = pd.DataFrame({'price': price,
'high': high,
'low': low,
'open': open_,
'volume': volume,
'arbitrary': arbitrary},
index=index)
panel = pd.Panel.from_dict({0: df})
return DataPanelSource(panel), panel