Files
catalyst/zipline/utils/events.py
T
Andrew Liang 8aac0ab19f BUG: Week rule plus time rule doesn't work
The next trigger for the week rule get recalculated every time
the rule is triggered
2016-04-18 17:05:43 -04:00

711 lines
21 KiB
Python

#
# Copyright 2014 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.
from abc import ABCMeta, abstractmethod
from collections import namedtuple
import six
import datetime
import pandas as pd
import pytz
from .context_tricks import nop_context
__all__ = [
'EventManager',
'Event',
'EventRule',
'StatelessRule',
'ComposedRule',
'Always',
'Never',
'AfterOpen',
'BeforeClose',
'NotHalfDay',
'NthTradingDayOfWeek',
'NDaysBeforeLastTradingDayOfWeek',
'NthTradingDayOfMonth',
'NDaysBeforeLastTradingDayOfMonth',
'StatefulRule',
'OncePerDay',
# Factory API
'DateRuleFactory',
'TimeRuleFactory',
'date_rules',
'time_rules',
'make_eventrule',
]
MAX_MONTH_RANGE = 26
MAX_WEEK_RANGE = 5
def naive_to_utc(ts):
"""
Converts a UTC tz-naive timestamp to a tz-aware timestamp.
"""
# Drop the nanoseconds field. warn=False suppresses the warning
# that we are losing the nanoseconds; however, this is intended.
return pd.Timestamp(ts.to_pydatetime(warn=False), tz='UTC')
def ensure_utc(time, tz='UTC'):
"""
Normalize a time. If the time is tz-naive, assume it is UTC.
"""
if not time.tzinfo:
time = time.replace(tzinfo=pytz.timezone(tz))
return time.replace(tzinfo=pytz.utc)
def _coerce_datetime(maybe_dt):
if isinstance(maybe_dt, datetime.datetime):
return maybe_dt
elif isinstance(maybe_dt, datetime.date):
return datetime.datetime(
year=maybe_dt.year,
month=maybe_dt.month,
day=maybe_dt.day,
tzinfo=pytz.utc,
)
elif isinstance(maybe_dt, (tuple, list)) and len(maybe_dt) == 3:
year, month, day = maybe_dt
return datetime.datetime(
year=year,
month=month,
day=day,
tzinfo=pytz.utc,
)
else:
raise TypeError('Cannot coerce %s into a datetime.datetime'
% type(maybe_dt).__name__)
def _out_of_range_error(a, b=None, var='offset'):
start = 0
if b is None:
end = a - 1
else:
start = a
end = b - 1
return ValueError(
'{var} must be in between {start} and {end} inclusive'.format(
var=var,
start=start,
end=end,
)
)
def _td_check(td):
seconds = td.total_seconds()
# 23400 seconds is 6 hours and 30 minutes.
if 60 <= seconds <= 23400:
return td
else:
raise ValueError('offset must be in between 1 minute and 6 hours and'
' 30 minutes inclusive')
def _build_offset(offset, kwargs, default):
"""
Builds the offset argument for event rules.
"""
if offset is None:
if not kwargs:
return default # use the default.
else:
return _td_check(datetime.timedelta(**kwargs))
elif kwargs:
raise ValueError('Cannot pass kwargs and an offset')
elif isinstance(offset, datetime.timedelta):
return _td_check(offset)
else:
raise TypeError("Must pass 'hours' and/or 'minutes' as keywords")
def _build_date(date, kwargs):
"""
Builds the date argument for event rules.
"""
if date is None:
if not kwargs:
raise ValueError('Must pass a date or kwargs')
else:
return datetime.date(**kwargs)
elif kwargs:
raise ValueError('Cannot pass kwargs and a date')
else:
return date
def _build_time(time, kwargs):
"""
Builds the time argument for event rules.
"""
tz = kwargs.pop('tz', 'UTC')
if time:
if kwargs:
raise ValueError('Cannot pass kwargs and a time')
else:
return ensure_utc(time, tz)
elif not kwargs:
raise ValueError('Must pass a time or kwargs')
else:
return datetime.time(**kwargs)
class EventManager(object):
"""Manages a list of Event objects.
This manages the logic for checking the rules and dispatching to the
handle_data function of the Events.
Parameters
----------
create_context : (BarData) -> context manager, optional
An optional callback to produce a context manager to wrap the calls
to handle_data. This will be passed the current BarData.
"""
def __init__(self, create_context=None):
self._events = []
self._create_context = (
create_context
if create_context is not None else
lambda *_: nop_context
)
def add_event(self, event, prepend=False):
"""
Adds an event to the manager.
"""
if prepend:
self._events.insert(0, event)
else:
self._events.append(event)
def handle_data(self, context, data, dt):
with self._create_context(data):
for event in self._events:
event.handle_data(
context,
data,
dt,
context.trading_environment,
)
class Event(namedtuple('Event', ['rule', 'callback'])):
"""
An event is a pairing of an EventRule and a callable that will be invoked
with the current algorithm context, data, and datetime only when the rule
is triggered.
"""
def __new__(cls, rule=None, callback=None):
callback = callback or (lambda *args, **kwargs: None)
return super(cls, cls).__new__(cls, rule=rule, callback=callback)
def handle_data(self, context, data, dt, env):
"""
Calls the callable only when the rule is triggered.
"""
if self.rule.should_trigger(dt, env):
self.callback(context, data)
class EventRule(six.with_metaclass(ABCMeta)):
@abstractmethod
def should_trigger(self, dt, env):
"""
Checks if the rule should trigger with its current state.
This method should be pure and NOT mutate any state on the object.
"""
raise NotImplementedError('should_trigger')
class StatelessRule(EventRule):
"""
A stateless rule has no observable side effects.
This is reentrant and will always give the same result for the
same datetime.
Because these are pure, they can be composed to create new rules.
"""
def and_(self, rule):
"""
Logical and of two rules, triggers only when both rules trigger.
This follows the short circuiting rules for normal and.
"""
return ComposedRule(self, rule, ComposedRule.lazy_and)
__and__ = and_
class ComposedRule(StatelessRule):
"""
A rule that composes the results of two rules with some composing function.
The composing function should be a binary function that accepts the results
first(dt) and second(dt) as positional arguments.
For example, operator.and_.
If lazy=True, then the lazy composer is used instead. The lazy composer
expects a function that takes the two should_trigger functions and the
datetime. This is useful of you don't always want to call should_trigger
for one of the rules. For example, this is used to implement the & and |
operators so that they will have the same short circuit logic that is
expected.
"""
def __init__(self, first, second, composer):
if not (isinstance(first, StatelessRule) and
isinstance(second, StatelessRule)):
raise ValueError('Only two StatelessRules can be composed')
self.first = first
self.second = second
self.composer = composer
def should_trigger(self, dt, env):
"""
Composes the two rules with a lazy composer.
"""
return self.composer(
self.first.should_trigger,
self.second.should_trigger,
dt,
env
)
@staticmethod
def lazy_and(first_should_trigger, second_should_trigger, dt, env):
"""
Lazily ands the two rules. This will NOT call the should_trigger of the
second rule if the first one returns False.
"""
return first_should_trigger(dt, env) and second_should_trigger(dt, env)
class Always(StatelessRule):
"""
A rule that always triggers.
"""
@staticmethod
def always_trigger(dt, env):
"""
A should_trigger implementation that will always trigger.
"""
return True
should_trigger = always_trigger
class Never(StatelessRule):
"""
A rule that never triggers.
"""
@staticmethod
def never_trigger(dt, env):
"""
A should_trigger implementation that will never trigger.
"""
return False
should_trigger = never_trigger
class AfterOpen(StatelessRule):
"""
A rule that triggers for some offset after the market opens.
Example that triggers after 30 minutes of the market opening:
>>> AfterOpen(minutes=30)
"""
def __init__(self, offset=None, **kwargs):
self.offset = _build_offset(
offset,
kwargs,
datetime.timedelta(minutes=1), # Defaults to the first minute.
)
self._period_start = None
self._period_end = None
self._period_close = None
self._one_minute = datetime.timedelta(minutes=1)
def calculate_dates(self, dt, env):
# given a dt, find that day's open and period end (open + offset)
self._period_start, self._period_close = env.get_open_and_close(dt)
self._period_end = \
self._period_start + self.offset - self._one_minute
def should_trigger(self, dt, env):
# There are two reasons why we might want to recalculate the dates.
# One is the first time we ever call should_trigger, when
# self._period_start is none. The second is when we're on a new day,
# and need to recalculate the dates. For performance reasons, we rely
# on the fact that our clock only ever ticks forward, since it's
# cheaper to do dt1 <= dt2 than dt1.date() != dt2.date(). This means
# that we will NOT correctly recognize a new date if we go backwards
# in time(which should never happen in a simulation, or in a live
# trading environment)
if (
self._period_start is None or
self._period_close <= dt
):
self.calculate_dates(dt, env)
return dt == self._period_end
class BeforeClose(StatelessRule):
"""
A rule that triggers for some offset time before the market closes.
Example that triggers for the last 30 minutes every day:
>>> BeforeClose(minutes=30)
"""
def __init__(self, offset=None, **kwargs):
self.offset = _build_offset(
offset,
kwargs,
datetime.timedelta(minutes=1), # Defaults to the last minute.
)
self._period_start = None
self._period_end = None
self._one_minute = datetime.timedelta(minutes=1)
def calculate_dates(self, dt, env):
# given a dt, find that day's close and period start (close - offset)
self._period_end = env.get_open_and_close(dt)[1]
self._period_start = \
self._period_end - self.offset
self._period_close = self._period_end
def should_trigger(self, dt, env):
# There are two reasons why we might want to recalculate the dates.
# One is the first time we ever call should_trigger, when
# self._period_start is none. The second is when we're on a new day,
# and need to recalculate the dates. For performance reasons, we rely
# on the fact that our clock only ever ticks forward, since it's
# cheaper to do dt1 <= dt2 than dt1.date() != dt2.date(). This means
# that we will NOT correctly recognize a new date if we go backwards
# in time(which should never happen in a simulation, or in a live
# trading environment)
if (
self._period_start is None or
self._period_close <= dt
):
self.calculate_dates(dt, env)
return self._period_start == dt
class NotHalfDay(StatelessRule):
"""
A rule that only triggers when it is not a half day.
"""
def should_trigger(self, dt, env):
return dt.date() not in env.early_closes
class TradingDayOfWeekRule(six.with_metaclass(ABCMeta, StatelessRule)):
def __init__(self, n=0):
if not 0 <= abs(n) < MAX_WEEK_RANGE:
raise _out_of_range_error(MAX_WEEK_RANGE)
self.td_delta = n
self.next_date_start = None
self.next_date_end = None
self.next_midnight_timestamp = None
@abstractmethod
def date_func(self, dt, env):
raise NotImplementedError
def calculate_start_and_end(self, dt, env):
next_trading_day = _coerce_datetime(
env.add_trading_days(
self.td_delta,
self.date_func(dt, env),
)
)
# If after applying the offset to the start/end day of the week, we get
# day in a different week, skip this week and go on to the next
while next_trading_day.isocalendar()[1] != dt.isocalendar()[1]:
dt += datetime.timedelta(days=7)
next_trading_day = _coerce_datetime(
env.add_trading_days(
self.td_delta,
self.date_func(dt, env),
)
)
next_open, next_close = env.get_open_and_close(next_trading_day)
self.next_date_start = next_open
self.next_date_end = next_close
self.next_midnight_timestamp = next_trading_day
def should_trigger(self, dt, env):
if self.next_date_start is None:
# First time this method has been called. Calculate the midnight,
# open, and close for the first trigger, which occurs on the week
# of the simulation start
self.calculate_start_and_end(dt, env)
# If we've passed the trigger, calculate the next one
if dt > self.next_date_end:
self.calculate_start_and_end(self.next_date_end +
datetime.timedelta(days=7),
env)
# if the given dt is within the next matching day, return true.
if self.next_date_start <= dt <= self.next_date_end or \
dt == self.next_midnight_timestamp:
return True
return False
class NthTradingDayOfWeek(TradingDayOfWeekRule):
"""
A rule that triggers on the nth trading day of the week.
This is zero-indexed, n=0 is the first trading day of the week.
"""
@staticmethod
def get_first_trading_day_of_week(dt, env):
prev = dt
dt = env.previous_trading_day(dt)
# If we're on the first trading day of the TradingEnvironment,
# calling previous_trading_day on it will return None, which
# will blow up when we try and call .date() on it. The first
# trading day of the env is also the first trading day of the
# week(in the TradingEnvironment, at least), so just return
# that date.
if dt is None:
return prev
while dt.date().weekday() < prev.date().weekday():
prev = dt
dt = env.previous_trading_day(dt)
if dt is None:
return prev
if env.is_trading_day(prev):
return prev.date()
else:
return env.next_trading_day(prev).date()
date_func = get_first_trading_day_of_week
class NDaysBeforeLastTradingDayOfWeek(TradingDayOfWeekRule):
"""
A rule that triggers n days before the last trading day of the week.
"""
def __init__(self, n):
super(NDaysBeforeLastTradingDayOfWeek, self).__init__(-n)
@staticmethod
def get_last_trading_day_of_week(dt, env):
prev = dt
dt = env.next_trading_day(dt)
# Traverse forward until we hit a week border, then jump back to the
# previous trading day.
while dt.date().weekday() > prev.date().weekday():
prev = dt
dt = env.next_trading_day(dt)
if env.is_trading_day(prev):
return prev.date()
else:
return env.previous_trading_day(prev).date()
date_func = get_last_trading_day_of_week
class NthTradingDayOfMonth(StatelessRule):
"""
A rule that triggers on the nth trading day of the month.
This is zero-indexed, n=0 is the first trading day of the month.
"""
def __init__(self, n=0):
if not 0 <= n < MAX_MONTH_RANGE:
raise _out_of_range_error(MAX_MONTH_RANGE)
self.td_delta = n
self.month = None
self.day = None
def should_trigger(self, dt, env):
return self.get_nth_trading_day_of_month(dt, env) == dt.date()
def get_nth_trading_day_of_month(self, dt, env):
if self.month == dt.month:
# We already computed the day for this month.
return self.day
if not self.td_delta:
self.day = self.get_first_trading_day_of_month(dt, env)
else:
self.day = env.add_trading_days(
self.td_delta,
self.get_first_trading_day_of_month(dt, env),
).date()
return self.day
def get_first_trading_day_of_month(self, dt, env):
self.month = dt.month
dt = dt.replace(day=1)
self.first_day = (dt if env.is_trading_day(dt)
else env.next_trading_day(dt)).date()
return self.first_day
class NDaysBeforeLastTradingDayOfMonth(StatelessRule):
"""
A rule that triggers n days before the last trading day of the month.
"""
def __init__(self, n=0):
if not 0 <= n < MAX_MONTH_RANGE:
raise _out_of_range_error(MAX_MONTH_RANGE)
self.td_delta = -n
self.month = None
self.day = None
def should_trigger(self, dt, env):
return self.get_nth_to_last_trading_day_of_month(dt, env) == dt.date()
def get_nth_to_last_trading_day_of_month(self, dt, env):
if self.month == dt.month:
# We already computed the last day for this month.
return self.day
if not self.td_delta:
self.day = self.get_last_trading_day_of_month(dt, env)
else:
self.day = env.add_trading_days(
self.td_delta,
self.get_last_trading_day_of_month(dt, env),
).date()
return self.day
def get_last_trading_day_of_month(self, dt, env):
self.month = dt.month
if dt.month == 12:
# Roll the year forward and start in January.
year = dt.year + 1
month = 1
else:
# Increment the month in the same year.
year = dt.year
month = dt.month + 1
self.last_day = env.previous_trading_day(
dt.replace(year=year, month=month, day=1)
).date()
return self.last_day
# Stateful rules
class StatefulRule(EventRule):
"""
A stateful rule has state.
This rule will give different results for the same datetimes depending
on the internal state that this holds.
StatefulRules wrap other rules as state transformers.
"""
def __init__(self, rule=None):
self.rule = rule or Always()
def new_should_trigger(self, callable_):
"""
Replace the should trigger implementation for the current rule.
"""
self.should_trigger = callable_
class OncePerDay(StatefulRule):
def __init__(self, rule=None):
self.triggered = False
self.date = None
self.next_date = None
super(OncePerDay, self).__init__(rule)
def should_trigger(self, dt, env):
if self.date is None or dt >= self.next_date:
# initialize or reset for new date
self.triggered = False
self.date = dt
# record the timestamp for the next day, so that we can use it
# to know if we've moved to the next day
self.next_date = dt + pd.Timedelta(1, unit="d")
if not self.triggered and self.rule.should_trigger(dt, env):
self.triggered = True
return True
# Factory API
class DateRuleFactory(object):
every_day = Always
@staticmethod
def month_start(days_offset=0):
return NthTradingDayOfMonth(n=days_offset)
@staticmethod
def month_end(days_offset=0):
return NDaysBeforeLastTradingDayOfMonth(n=days_offset)
@staticmethod
def week_start(days_offset=0):
return NthTradingDayOfWeek(n=days_offset)
@staticmethod
def week_end(days_offset=0):
return NDaysBeforeLastTradingDayOfWeek(n=days_offset)
class TimeRuleFactory(object):
market_open = AfterOpen
market_close = BeforeClose
# Convenience aliases.
date_rules = DateRuleFactory
time_rules = TimeRuleFactory
def make_eventrule(date_rule, time_rule, half_days=True):
"""
Constructs an event rule from the factory api.
"""
if half_days:
inner_rule = date_rule & time_rule
else:
inner_rule = date_rule & time_rule & NotHalfDay()
return OncePerDay(rule=inner_rule)