# # Copyright 2015 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 copy import copy import operator as op import warnings import logbook import pytz import pandas as pd from contextlib2 import ExitStack from pandas.tseries.tools import normalize_date import numpy as np from itertools import chain, repeat from numbers import Integral from six import ( exec_, iteritems, itervalues, string_types, ) from zipline._protocol import handle_non_market_minutes from zipline.assets.synthetic import make_simple_equity_info from zipline.data.data_portal import DataPortal from zipline.errors import ( AttachPipelineAfterInitialize, HistoryInInitialize, NoSuchPipeline, OrderDuringInitialize, PipelineOutputDuringInitialize, RegisterAccountControlPostInit, RegisterTradingControlPostInit, SetBenchmarkOutsideInitialize, SetCommissionPostInit, SetSlippagePostInit, UnsupportedCommissionModel, UnsupportedDatetimeFormat, UnsupportedOrderParameters, UnsupportedSlippageModel, CannotOrderDelistedAsset, UnsupportedCancelPolicy, SetCancelPolicyPostInit, OrderInBeforeTradingStart) from zipline.finance.trading import TradingEnvironment from zipline.finance.blotter import Blotter from zipline.finance.commission import PerShare, PerTrade, PerDollar from zipline.finance.controls import ( LongOnly, MaxOrderCount, MaxOrderSize, MaxPositionSize, MaxLeverage, RestrictedListOrder ) from zipline.finance.execution import ( LimitOrder, MarketOrder, StopLimitOrder, StopOrder, ) from zipline.finance.performance import PerformanceTracker from zipline.finance.slippage import ( VolumeShareSlippage, SlippageModel ) from zipline.finance.cancel_policy import NeverCancel, CancelPolicy from zipline.assets import Asset, Equity, Future from zipline.assets.futures import FutureChain from zipline.gens.tradesimulation import AlgorithmSimulator from zipline.pipeline.engine import ( NoOpPipelineEngine, SimplePipelineEngine, ) from zipline.utils.api_support import ( api_method, require_initialized, require_not_initialized, ZiplineAPI, disallowed_in_before_trading_start) from zipline.utils.input_validation import ensure_upper_case, error_keywords from zipline.utils.cache import CachedObject, Expired import zipline.utils.events from zipline.utils.events import ( EventManager, make_eventrule, DateRuleFactory, TimeRuleFactory, ) from zipline.utils.factory import create_simulation_parameters from zipline.utils.functional import unzip from zipline.utils.math_utils import ( tolerant_equals, round_if_near_integer ) from zipline.utils.preprocess import preprocess import zipline.protocol from zipline.sources.requests_csv import PandasRequestsCSV from zipline.gens.sim_engine import ( MinuteSimulationClock, DailySimulationClock, ) from zipline.sources.benchmark_source import BenchmarkSource from zipline.zipline_warnings import ZiplineDeprecationWarning DEFAULT_CAPITAL_BASE = float("1.0e5") log = logbook.Logger("ZiplineLog") class TradingAlgorithm(object): """A class that represents a trading strategy and parameters to execute the strategy. Parameters ---------- *args, **kwargs Forwarded to ``initialize`` unless listed below. initialize : callable[context -> None], optional Function that is called at the start of the simulation to setup the initial context. handle_data : callable[(context, data) -> None], optional Function called on every bar. This is where most logic should be implemented. before_trading_start : callable[(context, data) -> None], optional Function that is called before any bars have been processed each day. analyze : callable[(context, DataFrame) -> None], optional Function that is called at the end of the backtest. This is passed the context and the performance results for the backtest. script : str, optional Algoscript that contains the definitions for the four algorithm lifecycle functions and any supporting code. namespace : dict, optional The namespace to execute the algoscript in. By default this is an empty namespace that will include only python built ins. algo_filename : str, optional The filename for the algoscript. This will be used in exception tracebacks. default: ''. data_frequency : {'daily', 'minute'}, optional The duration of the bars. capital_base : float, optional How much capital to start with. default: 1.0e5 instant_fill : bool, optional Whether to fill orders immediately or on next bar. default: False equities_metadata : dict or DataFrame or file-like object, optional If dict is provided, it must have the following structure: * keys are the identifiers * values are dicts containing the metadata, with the metadata field name as the key If pandas.DataFrame is provided, it must have the following structure: * column names must be the metadata fields * index must be the different asset identifiers * array contents should be the metadata value If an object with a ``read`` method is provided, ``read`` must return rows containing at least one of 'sid' or 'symbol' along with the other metadata fields. futures_metadata : dict or DataFrame or file-like object, optional The same layout as ``equities_metadata`` except that it is used for futures information. identifiers : list, optional Any asset identifiers that are not provided in the equities_metadata, but will be traded by this TradingAlgorithm. get_pipeline_loader : callable[BoundColumn -> PipelineLoader], optional The function that maps pipeline columns to their loaders. create_event_context : callable[BarData -> context manager], optional A function used to create a context mananger that wraps the execution of all events that are scheduled for a bar. This function will be passed the data for the bar and should return the actual context manager that will be entered. history_container_class : type, optional The type of history container to use. default: HistoryContainer platform : str, optional The platform the simulation is running on. This can be queried for in the simulation with ``get_environment``. This allows algorithms to conditionally execute code based on platform it is running on. default: 'zipline' """ def __init__(self, *args, **kwargs): """Initialize sids and other state variables. :Arguments: :Optional: initialize : function Function that is called with a single argument at the begninning of the simulation. handle_data : function Function that is called with 2 arguments (context and data) on every bar. script : str Algoscript that contains initialize and handle_data function definition. data_frequency : {'daily', 'minute'} The duration of the bars. capital_base : float How much capital to start with. asset_finder : An AssetFinder object A new AssetFinder object to be used in this TradingEnvironment equities_metadata : can be either: - dict - pandas.DataFrame - object with 'read' property If dict is provided, it must have the following structure: * keys are the identifiers * values are dicts containing the metadata, with the metadata field name as the key If pandas.DataFrame is provided, it must have the following structure: * column names must be the metadata fields * index must be the different asset identifiers * array contents should be the metadata value If an object with a 'read' property is provided, 'read' must return rows containing at least one of 'sid' or 'symbol' along with the other metadata fields. identifiers : List Any asset identifiers that are not provided in the equities_metadata, but will be traded by this TradingAlgorithm """ self.sources = [] # List of trading controls to be used to validate orders. self.trading_controls = [] # List of account controls to be checked on each bar. self.account_controls = [] self._recorded_vars = {} self.namespace = kwargs.pop('namespace', {}) self._platform = kwargs.pop('platform', 'zipline') self.logger = None self.data_portal = kwargs.pop('data_portal', None) # If an env has been provided, pop it self.trading_environment = kwargs.pop('env', None) if self.trading_environment is None: self.trading_environment = TradingEnvironment() # Update the TradingEnvironment with the provided asset metadata if 'equities_metadata' in kwargs or 'futures_metadata' in kwargs: warnings.warn( 'passing metadata to TradingAlgorithm is deprecated; please' ' write this data into the asset db before passing it to the' ' trading environment', DeprecationWarning, stacklevel=1, ) self.trading_environment.write_data( equities=kwargs.pop('equities_metadata', None), futures=kwargs.pop('futures_metadata', None), ) # set the capital base self.capital_base = kwargs.pop('capital_base', DEFAULT_CAPITAL_BASE) self.sim_params = kwargs.pop('sim_params', None) if self.sim_params is None: self.sim_params = create_simulation_parameters( capital_base=self.capital_base, start=kwargs.pop('start', None), end=kwargs.pop('end', None), env=self.trading_environment, ) else: self.sim_params.update_internal_from_env(self.trading_environment) self.perf_tracker = None # Pull in the environment's new AssetFinder for quick reference self.asset_finder = self.trading_environment.asset_finder # Initialize Pipeline API data. self.init_engine(kwargs.pop('get_pipeline_loader', None)) self._pipelines = {} # Create an always-expired cache so that we compute the first time data # is requested. self._pipeline_cache = CachedObject(None, pd.Timestamp(0, tz='UTC')) self.blotter = kwargs.pop('blotter', None) self.cancel_policy = kwargs.pop('cancel_policy', NeverCancel()) if not self.blotter: self.blotter = Blotter( data_frequency=self.data_frequency, asset_finder=self.asset_finder, slippage_func=VolumeShareSlippage(), commission=PerShare(), # Default to NeverCancel in zipline cancel_policy=self.cancel_policy ) # The symbol lookup date specifies the date to use when resolving # symbols to sids, and can be set using set_symbol_lookup_date() self._symbol_lookup_date = None self.portfolio_needs_update = True self.account_needs_update = True self.performance_needs_update = True self._portfolio = None self._account = None # If string is passed in, execute and get reference to # functions. self.algoscript = kwargs.pop('script', None) self._initialize = None self._before_trading_start = None self._analyze = None self._in_before_trading_start = False self.event_manager = EventManager( create_context=kwargs.pop('create_event_context', None), ) self._handle_data = None if self.algoscript is not None: filename = kwargs.pop('algo_filename', None) if filename is None: filename = '' code = compile(self.algoscript, filename, 'exec') exec_(code, self.namespace) self._initialize = self.namespace.get('initialize') if 'handle_data' in self.namespace: self._handle_data = self.namespace['handle_data'] self._before_trading_start = \ self.namespace.get('before_trading_start') # Optional analyze function, gets called after run self._analyze = self.namespace.get('analyze') elif kwargs.get('initialize') and kwargs.get('handle_data'): if self.algoscript is not None: raise ValueError('You can not set script and \ initialize/handle_data.') self._initialize = kwargs.pop('initialize') self._handle_data = kwargs.pop('handle_data') self._before_trading_start = kwargs.pop('before_trading_start', None) self._analyze = kwargs.pop('analyze', None) self.event_manager.add_event( zipline.utils.events.Event( zipline.utils.events.Always(), # We pass handle_data.__func__ to get the unbound method. # We will explicitly pass the algorithm to bind it again. self.handle_data.__func__, ), prepend=True, ) # If method not defined, NOOP if self._initialize is None: self._initialize = lambda x: None # Alternative way of setting data_frequency for backwards # compatibility. if 'data_frequency' in kwargs: self.data_frequency = kwargs.pop('data_frequency') # Prepare the algo for initialization self.initialized = False self.initialize_args = args self.initialize_kwargs = kwargs self.benchmark_sid = kwargs.pop('benchmark_sid', None) def init_engine(self, get_loader): """ Construct and store a PipelineEngine from loader. If get_loader is None, constructs a NoOpPipelineEngine. """ if get_loader is not None: self.engine = SimplePipelineEngine( get_loader, self.trading_environment.trading_days, self.asset_finder, ) else: self.engine = NoOpPipelineEngine() def initialize(self, *args, **kwargs): """ Call self._initialize with `self` made available to Zipline API functions. """ with ZiplineAPI(self): self._initialize(self, *args, **kwargs) def before_trading_start(self, data): if self._before_trading_start is None: return self._in_before_trading_start = True with handle_non_market_minutes(data) if \ self.data_frequency == "minute" else ExitStack(): self._before_trading_start(self, data) self._in_before_trading_start = False def handle_data(self, data): if self._handle_data: self._handle_data(self, data) # Unlike trading controls which remain constant unless placing an # order, account controls can change each bar. Thus, must check # every bar no matter if the algorithm places an order or not. self.validate_account_controls() def analyze(self, perf): if self._analyze is None: return with ZiplineAPI(self): self._analyze(self, perf) def __repr__(self): """ N.B. this does not yet represent a string that can be used to instantiate an exact copy of an algorithm. However, it is getting close, and provides some value as something that can be inspected interactively. """ return """ {class_name}( capital_base={capital_base} sim_params={sim_params}, initialized={initialized}, slippage={slippage}, commission={commission}, blotter={blotter}, recorded_vars={recorded_vars}) """.strip().format(class_name=self.__class__.__name__, capital_base=self.capital_base, sim_params=repr(self.sim_params), initialized=self.initialized, slippage=repr(self.blotter.slippage_func), commission=repr(self.blotter.commission), blotter=repr(self.blotter), recorded_vars=repr(self.recorded_vars)) def _create_clock(self): """ If the clock property is not set, then create one based on frequency. """ if self.sim_params.data_frequency == 'minute': env = self.trading_environment trading_o_and_c = env.open_and_closes.ix[ self.sim_params.trading_days] market_opens = trading_o_and_c['market_open'].values.astype( 'datetime64[ns]').astype(np.int64) market_closes = trading_o_and_c['market_close'].values.astype( 'datetime64[ns]').astype(np.int64) minutely_emission = self.sim_params.emission_rate == "minute" clock = MinuteSimulationClock( self.sim_params.trading_days, market_opens, market_closes, env.trading_days, minutely_emission ) return clock else: return DailySimulationClock(self.sim_params.trading_days) def _create_benchmark_source(self): return BenchmarkSource( self.benchmark_sid, self.trading_environment, self.sim_params.trading_days, self.data_portal, emission_rate=self.sim_params.emission_rate, ) def _create_generator(self, sim_params): if sim_params is not None: self.sim_params = sim_params if self.perf_tracker is None: # HACK: When running with the `run` method, we set perf_tracker to # None so that it will be overwritten here. self.perf_tracker = PerformanceTracker( sim_params=self.sim_params, env=self.trading_environment, ) # Set the dt initially to the period start by forcing it to change. self.on_dt_changed(self.sim_params.period_start) if not self.initialized: self.initialize(*self.initialize_args, **self.initialize_kwargs) self.initialized = True self.trading_client = AlgorithmSimulator( self, sim_params, self.data_portal, self._create_clock(), self._create_benchmark_source(), universe_func=self._calculate_universe ) return self.trading_client.transform() def _calculate_universe(self): # this exists to provide backwards compatibility for older, # deprecated APIs, particularly around the iterability of # BarData (ie, 'for sid in data`). # our universe is all the assets passed into `run`. return self._assets_from_source def get_generator(self): """ Override this method to add new logic to the construction of the generator. Overrides can use the _create_generator method to get a standard construction generator. """ return self._create_generator(self.sim_params) def run(self, data=None, overwrite_sim_params=True): """Run the algorithm. :Arguments: source : DataPortal :Returns: daily_stats : pandas.DataFrame Daily performance metrics such as returns, alpha etc. """ self._assets_from_source = [] if isinstance(data, DataPortal): self.data_portal = data # define the universe as all the assets in the assetfinder # This is not great, because multiple runs can accumulate assets # in the assetfinder, but it's better than spending time adding # functionality in the dataportal to report all the assets it # knows about. self._assets_from_source = \ self.trading_environment.asset_finder.retrieve_all( self.trading_environment.asset_finder.sids ) else: if isinstance(data, pd.DataFrame): # If a DataFrame is passed. Promote it to a Panel. # The reader will fake volume values. data = pd.Panel({'close': data.copy()}) data = data.swapaxes(0, 2) if isinstance(data, pd.Panel): # For compatibility with existing examples allow start/end # to be inferred. if overwrite_sim_params: self.sim_params.period_start = data.major_axis[0] self.sim_params.period_end = data.major_axis[-1] # Changing period_start and period_close might require # updating of first_open and last_close. self.sim_params.update_internal_from_env( env=self.trading_environment ) copy_panel = data.copy() copy_panel.items = self._write_and_map_id_index_to_sids( copy_panel.items, copy_panel.major_axis[0], ) self._assets_from_source = \ set(self.trading_environment.asset_finder.retrieve_all( copy_panel.items )) equities = [] for asset in self._assets_from_source: if isinstance(asset, Equity): equities.append(asset) if equities: from zipline.data.us_equity_pricing import \ PanelDailyBarReader equity_daily_reader = PanelDailyBarReader( self.trading_environment.trading_days, copy_panel) else: equity_daily_reader = None self.data_portal = DataPortal( self.trading_environment, equity_daily_reader=equity_daily_reader) # Force a reset of the performance tracker, in case # this is a repeat run of the algorithm. self.perf_tracker = None # Create zipline and loop through simulated_trading. # Each iteration returns a perf dictionary try: perfs = [] for perf in self.get_generator(): perfs.append(perf) # convert perf dict to pandas dataframe daily_stats = self._create_daily_stats(perfs) self.analyze(daily_stats) finally: self.data_portal = None return daily_stats def _write_and_map_id_index_to_sids(self, identifiers, as_of_date): # Build new Assets for identifiers that can't be resolved as # sids/Assets identifiers_to_build = set() next_sid = max(self.asset_finder.sids or (0,)) + 1 for identifier in identifiers: asset = None if isinstance(identifier, Asset): asset = self.asset_finder.retrieve_asset(sid=identifier.sid, default_none=True) elif isinstance(identifier, Integral): asset = self.asset_finder.retrieve_asset(sid=identifier, default_none=True) if asset is None: try: sid = op.index(identifier) except TypeError: sid = next_sid next_sid += 1 identifiers_to_build.add((identifier, sid)) if identifiers_to_build: warnings.warn( 'writing unknown identifiers into the assets db of the trading' ' environment is deprecated; please write this information' ' to the assets db before constructing the environment', DeprecationWarning, stacklevel=2, ) symbols, sids = unzip(identifiers_to_build, 2) self.trading_environment.write_data( equities=make_simple_equity_info( sids, start_date=self.sim_params.period_start, end_date=self.sim_params.period_end, symbols=symbols, ), ) # We need to clear out any cache misses that were stored while trying # to do lookups. The real fix for this problem is to not construct an # AssetFinder until we `run()` when we actually have all the data we # need to so. self.asset_finder._reset_caches() return self.asset_finder.map_identifier_index_to_sids( identifiers, as_of_date, ) def _create_daily_stats(self, perfs): # create daily and cumulative stats dataframe daily_perfs = [] # TODO: the loop here could overwrite expected properties # of daily_perf. Could potentially raise or log a # warning. for perf in perfs: if 'daily_perf' in perf: perf['daily_perf'].update( perf['daily_perf'].pop('recorded_vars') ) perf['daily_perf'].update(perf['cumulative_risk_metrics']) daily_perfs.append(perf['daily_perf']) else: self.risk_report = perf daily_dts = [np.datetime64(perf['period_close'], utc=True) for perf in daily_perfs] daily_stats = pd.DataFrame(daily_perfs, index=daily_dts) return daily_stats @api_method def get_environment(self, field='platform'): env = { 'arena': self.sim_params.arena, 'data_frequency': self.sim_params.data_frequency, 'start': self.sim_params.first_open, 'end': self.sim_params.last_close, 'capital_base': self.sim_params.capital_base, 'platform': self._platform } if field == '*': return env else: return env[field] @api_method def fetch_csv(self, url, pre_func=None, post_func=None, date_column='date', date_format=None, timezone=pytz.utc.zone, symbol=None, mask=True, symbol_column=None, special_params_checker=None, **kwargs): # Show all the logs every time fetcher is used. csv_data_source = PandasRequestsCSV( url, pre_func, post_func, self.trading_environment, self.sim_params.period_start, self.sim_params.period_end, date_column, date_format, timezone, symbol, mask, symbol_column, data_frequency=self.data_frequency, special_params_checker=special_params_checker, **kwargs ) # ingest this into dataportal self.data_portal.handle_extra_source(csv_data_source.df, self.sim_params) return csv_data_source def add_event(self, rule=None, callback=None): """ Adds an event to the algorithm's EventManager. """ self.event_manager.add_event( zipline.utils.events.Event(rule, callback), ) @api_method def schedule_function(self, func, date_rule=None, time_rule=None, half_days=True): """ Schedules a function to be called with some timed rules. """ date_rule = date_rule or DateRuleFactory.every_day() time_rule = ((time_rule or TimeRuleFactory.market_open()) if self.sim_params.data_frequency == 'minute' else # If we are in daily mode the time_rule is ignored. zipline.utils.events.Always()) self.add_event( make_eventrule(date_rule, time_rule, half_days), func, ) @api_method def record(self, *args, **kwargs): """ Track and record local variable (i.e. attributes) each day. """ # Make 2 objects both referencing the same iterator args = [iter(args)] * 2 # Zip generates list entries by calling `next` on each iterator it # receives. In this case the two iterators are the same object, so the # call to next on args[0] will also advance args[1], resulting in zip # returning (a,b) (c,d) (e,f) rather than (a,a) (b,b) (c,c) etc. positionals = zip(*args) for name, value in chain(positionals, iteritems(kwargs)): self._recorded_vars[name] = value @api_method def set_benchmark(self, benchmark_sid): if self.initialized: raise SetBenchmarkOutsideInitialize() self.benchmark_sid = benchmark_sid @api_method @preprocess(symbol_str=ensure_upper_case) def symbol(self, symbol_str): """ Default symbol lookup for any source that directly maps the symbol to the Asset (e.g. yahoo finance). """ # If the user has not set the symbol lookup date, # use the period_end as the date for sybmol->sid resolution. _lookup_date = self._symbol_lookup_date if self._symbol_lookup_date is not None \ else self.sim_params.period_end return self.asset_finder.lookup_symbol( symbol_str, as_of_date=_lookup_date, ) @api_method def symbols(self, *args): """ Default symbols lookup for any source that directly maps the symbol to the Asset (e.g. yahoo finance). """ return [self.symbol(identifier) for identifier in args] @api_method def sid(self, a_sid): """ Default sid lookup for any source that directly maps the integer sid to the Asset. """ return self.asset_finder.retrieve_asset(a_sid) @api_method @preprocess(symbol=ensure_upper_case) def future_symbol(self, symbol): """ Lookup a futures contract with a given symbol. Parameters ---------- symbol : str The symbol of the desired contract. Returns ------- Future A Future object. Raises ------ SymbolNotFound Raised when no contract named 'symbol' is found. """ return self.asset_finder.lookup_future_symbol(symbol) @api_method @preprocess(root_symbol=ensure_upper_case) def future_chain(self, root_symbol, as_of_date=None): """ Look up a future chain with the specified parameters. Parameters ---------- root_symbol : str The root symbol of a future chain. as_of_date : datetime.datetime or pandas.Timestamp or str, optional Date at which the chain determination is rooted. I.e. the existing contract whose notice date is first after this date is the primary contract, etc. Returns ------- FutureChain The future chain matching the specified parameters. Raises ------ RootSymbolNotFound If a future chain could not be found for the given root symbol. """ if as_of_date: try: as_of_date = pd.Timestamp(as_of_date, tz='UTC') except ValueError: raise UnsupportedDatetimeFormat(input=as_of_date, method='future_chain') return FutureChain( asset_finder=self.asset_finder, get_datetime=self.get_datetime, root_symbol=root_symbol, as_of_date=as_of_date ) def _calculate_order_value_amount(self, asset, value): """ Calculates how many shares/contracts to order based on the type of asset being ordered. """ # Make sure the asset exists, and that there is a last price for it. # FIXME: we should use BarData's can_trade logic here, but I haven't # yet found a good way to do that. normalized_date = normalize_date(self.datetime) if normalized_date < asset.start_date: raise CannotOrderDelistedAsset( msg="Cannot order {0}, as it started trading on" " {1}.".format(asset.symbol, asset.start_date) ) elif normalized_date > asset.end_date: raise CannotOrderDelistedAsset( msg="Cannot order {0}, as it stopped trading on" " {1}.".format(asset.symbol, asset.end_date) ) else: last_price = \ self.trading_client.current_data.current(asset, "price") if np.isnan(last_price): raise CannotOrderDelistedAsset( msg="Cannot order {0} on {1} as there is no last " "price for the security.".format(asset.symbol, self.datetime) ) if tolerant_equals(last_price, 0): zero_message = "Price of 0 for {psid}; can't infer value".format( psid=asset ) if self.logger: self.logger.debug(zero_message) # Don't place any order return 0 if isinstance(asset, Future): value_multiplier = asset.multiplier else: value_multiplier = 1 return value / (last_price * value_multiplier) def _can_order_asset(self, asset): if not isinstance(asset, Asset): raise UnsupportedOrderParameters( msg="Passing non-Asset argument to 'order()' is not supported." " Use 'sid()' or 'symbol()' methods to look up an Asset." ) if asset.auto_close_date: day = normalize_date(self.get_datetime()) if asset.end_date < day < asset.auto_close_date: # we are between the asset's end date and auto close date, # so warn the user that they can't place an order for this # asset, and return None. log.warn("Cannot place order for {0}, as it has de-listed. " "Any existing positions for this asset will be " "liquidated on " "{1}.".format(asset.symbol, asset.auto_close_date)) return False return True @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order(self, asset, amount, limit_price=None, stop_price=None, style=None): """ Place an order using the specified parameters. """ if not self._can_order_asset(asset): return None # Truncate to the integer share count that's either within .0001 of # amount or closer to zero. # E.g. 3.9999 -> 4.0; 5.5 -> 5.0; -5.5 -> -5.0 amount = int(round_if_near_integer(amount)) # Raises a ZiplineError if invalid parameters are detected. self.validate_order_params(asset, amount, limit_price, stop_price, style) # Convert deprecated limit_price and stop_price parameters to use # ExecutionStyle objects. style = self.__convert_order_params_for_blotter(limit_price, stop_price, style) return self.blotter.order(asset, amount, style) def validate_order_params(self, asset, amount, limit_price, stop_price, style): """ Helper method for validating parameters to the order API function. Raises an UnsupportedOrderParameters if invalid arguments are found. """ if not self.initialized: raise OrderDuringInitialize( msg="order() can only be called from within handle_data()" ) if style: if limit_price: raise UnsupportedOrderParameters( msg="Passing both limit_price and style is not supported." ) if stop_price: raise UnsupportedOrderParameters( msg="Passing both stop_price and style is not supported." ) for control in self.trading_controls: control.validate(asset, amount, self.updated_portfolio(), self.get_datetime(), self.trading_client.current_data) @staticmethod def __convert_order_params_for_blotter(limit_price, stop_price, style): """ Helper method for converting deprecated limit_price and stop_price arguments into ExecutionStyle instances. This function assumes that either style == None or (limit_price, stop_price) == (None, None). """ # TODO_SS: DeprecationWarning for usage of limit_price and stop_price. if style: assert (limit_price, stop_price) == (None, None) return style if limit_price and stop_price: return StopLimitOrder(limit_price, stop_price) if limit_price: return LimitOrder(limit_price) if stop_price: return StopOrder(stop_price) else: return MarketOrder() @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order_value(self, asset, value, limit_price=None, stop_price=None, style=None): """ Place an order by desired value rather than desired number of shares. If the requested asset exists, the requested value is divided by its price to imply the number of shares to transact. If the Asset being ordered is a Future, the 'value' calculated is actually the exposure, as Futures have no 'value'. value > 0 :: Buy/Cover value < 0 :: Sell/Short Market order: order(sid, value) Limit order: order(sid, value, limit_price) Stop order: order(sid, value, None, stop_price) StopLimit order: order(sid, value, limit_price, stop_price) """ if not self._can_order_asset(asset): return None amount = self._calculate_order_value_amount(asset, value) return self.order(asset, amount, limit_price=limit_price, stop_price=stop_price, style=style) @property def recorded_vars(self): return copy(self._recorded_vars) @property def portfolio(self): return self.updated_portfolio() def updated_portfolio(self): if self.portfolio_needs_update: self.perf_tracker.position_tracker.sync_last_sale_prices( self.datetime, self._in_before_trading_start, self.data_portal) self._portfolio = \ self.perf_tracker.get_portfolio(self.performance_needs_update) self.portfolio_needs_update = False self.performance_needs_update = False return self._portfolio @property def account(self): return self.updated_account() def updated_account(self): if self.account_needs_update: self.perf_tracker.position_tracker.sync_last_sale_prices( self.datetime, self._in_before_trading_start, self.data_portal) self._account = \ self.perf_tracker.get_account(self.performance_needs_update) self.account_needs_update = False self.performance_needs_update = False return self._account def set_logger(self, logger): self.logger = logger def on_dt_changed(self, dt): """ Callback triggered by the simulation loop whenever the current dt changes. Any logic that should happen exactly once at the start of each datetime group should happen here. """ self.datetime = dt self.perf_tracker.set_date(dt) self.blotter.set_date(dt) self.portfolio_needs_update = True self.account_needs_update = True self.performance_needs_update = True @api_method def get_datetime(self, tz=None): """ Returns the simulation datetime. """ dt = self.datetime assert dt.tzinfo == pytz.utc, "Algorithm should have a utc datetime" if tz is not None: # Convert to the given timezone passed as a string or tzinfo. if isinstance(tz, string_types): tz = pytz.timezone(tz) dt = dt.astimezone(tz) return dt # datetime.datetime objects are immutable. def update_dividends(self, dividend_frame): """ Set DataFrame used to process dividends. DataFrame columns should contain at least the entries in zp.DIVIDEND_FIELDS. """ self.perf_tracker.update_dividends(dividend_frame) @api_method def set_slippage(self, slippage): if not isinstance(slippage, SlippageModel): raise UnsupportedSlippageModel() if self.initialized: raise SetSlippagePostInit() self.blotter.slippage_func = slippage @api_method def set_commission(self, commission): if not isinstance(commission, (PerShare, PerTrade, PerDollar)): raise UnsupportedCommissionModel() if self.initialized: raise SetCommissionPostInit() self.blotter.commission = commission @api_method def set_cancel_policy(self, cancel_policy): if not isinstance(cancel_policy, CancelPolicy): raise UnsupportedCancelPolicy() if self.initialized: raise SetCancelPolicyPostInit() self.blotter.cancel_policy = cancel_policy @api_method def set_symbol_lookup_date(self, dt): """ Set the date for which symbols will be resolved to their assets (symbols may map to different firms or underlying assets at different times) """ try: self._symbol_lookup_date = pd.Timestamp(dt, tz='UTC') except ValueError: raise UnsupportedDatetimeFormat(input=dt, method='set_symbol_lookup_date') # Remain backwards compatibility @property def data_frequency(self): return self.sim_params.data_frequency @data_frequency.setter def data_frequency(self, value): assert value in ('daily', 'minute') self.sim_params.data_frequency = value @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order_percent(self, asset, percent, limit_price=None, stop_price=None, style=None): """ Place an order in the specified asset corresponding to the given percent of the current portfolio value. Note that percent must expressed as a decimal (0.50 means 50\%). """ if not self._can_order_asset(asset): return None value = self.portfolio.portfolio_value * percent return self.order_value(asset, value, limit_price=limit_price, stop_price=stop_price, style=style) @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order_target(self, asset, target, limit_price=None, stop_price=None, style=None): """ Place an order to adjust a position to a target number of shares. If the position doesn't already exist, this is equivalent to placing a new order. If the position does exist, this is equivalent to placing an order for the difference between the target number of shares and the current number of shares. """ if not self._can_order_asset(asset): return None if asset in self.portfolio.positions: current_position = self.portfolio.positions[asset].amount req_shares = target - current_position return self.order(asset, req_shares, limit_price=limit_price, stop_price=stop_price, style=style) else: return self.order(asset, target, limit_price=limit_price, stop_price=stop_price, style=style) @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order_target_value(self, asset, target, limit_price=None, stop_price=None, style=None): """ Place an order to adjust a position to a target value. If the position doesn't already exist, this is equivalent to placing a new order. If the position does exist, this is equivalent to placing an order for the difference between the target value and the current value. If the Asset being ordered is a Future, the 'target value' calculated is actually the target exposure, as Futures have no 'value'. """ if not self._can_order_asset(asset): return None target_amount = self._calculate_order_value_amount(asset, target) return self.order_target(asset, target_amount, limit_price=limit_price, stop_price=stop_price, style=style) @api_method @disallowed_in_before_trading_start(OrderInBeforeTradingStart()) def order_target_percent(self, asset, target, limit_price=None, stop_price=None, style=None): """ Place an order to adjust a position to a target percent of the current portfolio value. If the position doesn't already exist, this is equivalent to placing a new order. If the position does exist, this is equivalent to placing an order for the difference between the target percent and the current percent. Note that target must expressed as a decimal (0.50 means 50\%). """ if not self._can_order_asset(asset): return None target_value = self.portfolio.portfolio_value * target return self.order_target_value(asset, target_value, limit_price=limit_price, stop_price=stop_price, style=style) @error_keywords(sid='Keyword argument `sid` is no longer supported for ' 'get_open_orders. Use `asset` instead.') @api_method def get_open_orders(self, asset=None): if asset is None: return { key: [order.to_api_obj() for order in orders] for key, orders in iteritems(self.blotter.open_orders) if orders } if asset in self.blotter.open_orders: orders = self.blotter.open_orders[asset] return [order.to_api_obj() for order in orders] return [] @api_method def get_order(self, order_id): if order_id in self.blotter.orders: return self.blotter.orders[order_id].to_api_obj() @api_method def cancel_order(self, order_param): order_id = order_param if isinstance(order_param, zipline.protocol.Order): order_id = order_param.id self.blotter.cancel(order_id) @api_method @require_initialized(HistoryInInitialize()) def history(self, bar_count, frequency, field, ffill=True): warnings.warn( "The `history` method is deprecated. Use `data.history` instead.", category=ZiplineDeprecationWarning, stacklevel=4 ) return self.get_history_window( bar_count, frequency, self._calculate_universe(), field, ffill ) def get_history_window(self, bar_count, frequency, assets, field, ffill): if not self._in_before_trading_start: return self.data_portal.get_history_window( assets, self.datetime, bar_count, frequency, field, ffill, ) else: # If we are in before_trading_start, we need to get the window # as of the previous market minute adjusted_dt = \ self.data_portal.env.previous_market_minute(self.datetime) window = self.data_portal.get_history_window( assets, adjusted_dt, bar_count, frequency, field, ffill, ) # Get the adjustments between the last market minute and the # current before_trading_start dt and apply to the window adjs = self.data_portal.get_adjustments( assets, field, adjusted_dt, self.datetime ) window = window * adjs return window #################### # Account Controls # #################### def register_account_control(self, control): """ Register a new AccountControl to be checked on each bar. """ if self.initialized: raise RegisterAccountControlPostInit() self.account_controls.append(control) def validate_account_controls(self): for control in self.account_controls: control.validate(self.updated_portfolio(), self.updated_account(), self.get_datetime(), self.trading_client.current_data) @api_method def set_max_leverage(self, max_leverage=None): """ Set a limit on the maximum leverage of the algorithm. """ control = MaxLeverage(max_leverage) self.register_account_control(control) #################### # Trading Controls # #################### def register_trading_control(self, control): """ Register a new TradingControl to be checked prior to order calls. """ if self.initialized: raise RegisterTradingControlPostInit() self.trading_controls.append(control) @api_method def set_max_position_size(self, asset=None, max_shares=None, max_notional=None): """ Set a limit on the number of shares and/or dollar value held for the given sid. Limits are treated as absolute values and are enforced at the time that the algo attempts to place an order for sid. This means that it's possible to end up with more than the max number of shares due to splits/dividends, and more than the max notional due to price improvement. If an algorithm attempts to place an order that would result in increasing the absolute value of shares/dollar value exceeding one of these limits, raise a TradingControlException. """ control = MaxPositionSize(asset=asset, max_shares=max_shares, max_notional=max_notional) self.register_trading_control(control) @api_method def set_max_order_size(self, asset=None, max_shares=None, max_notional=None): """ Set a limit on the number of shares and/or dollar value of any single order placed for sid. Limits are treated as absolute values and are enforced at the time that the algo attempts to place an order for sid. If an algorithm attempts to place an order that would result in exceeding one of these limits, raise a TradingControlException. """ control = MaxOrderSize(asset=asset, max_shares=max_shares, max_notional=max_notional) self.register_trading_control(control) @api_method def set_max_order_count(self, max_count): """ Set a limit on the number of orders that can be placed within the given time interval. """ control = MaxOrderCount(max_count) self.register_trading_control(control) @api_method def set_do_not_order_list(self, restricted_list): """ Set a restriction on which assets can be ordered. """ control = RestrictedListOrder(restricted_list) self.register_trading_control(control) @api_method def set_long_only(self): """ Set a rule specifying that this algorithm cannot take short positions. """ self.register_trading_control(LongOnly()) ############## # Pipeline API ############## @api_method @require_not_initialized(AttachPipelineAfterInitialize()) def attach_pipeline(self, pipeline, name, chunksize=None): """ Register a pipeline to be computed at the start of each day. """ if self._pipelines: raise NotImplementedError("Multiple pipelines are not supported.") if chunksize is None: # Make the first chunk smaller to get more immediate results: # (one week, then every half year) chunks = iter(chain([5], repeat(126))) else: chunks = iter(repeat(int(chunksize))) self._pipelines[name] = pipeline, chunks # Return the pipeline to allow expressions like # p = attach_pipeline(Pipeline(), 'name') return pipeline @api_method @require_initialized(PipelineOutputDuringInitialize()) def pipeline_output(self, name): """ Get the results of pipeline with name `name`. Parameters ---------- name : str Name of the pipeline for which results are requested. Returns ------- results : pd.DataFrame DataFrame containing the results of the requested pipeline for the current simulation date. Raises ------ NoSuchPipeline Raised when no pipeline with the name `name` has been registered. See Also -------- :meth:`zipline.pipeline.engine.PipelineEngine.run_pipeline` """ # NOTE: We don't currently support multiple pipelines, but we plan to # in the future. try: p, chunks = self._pipelines[name] except KeyError: raise NoSuchPipeline( name=name, valid=list(self._pipelines.keys()), ) return self._pipeline_output(p, chunks) def _pipeline_output(self, pipeline, chunks): """ Internal implementation of `pipeline_output`. """ today = normalize_date(self.get_datetime()) try: data = self._pipeline_cache.unwrap(today) except Expired: data, valid_until = self._run_pipeline( pipeline, today, next(chunks), ) self._pipeline_cache = CachedObject(data, valid_until) # Now that we have a cached result, try to return the data for today. try: return data.loc[today] except KeyError: # This happens if no assets passed the pipeline screen on a given # day. return pd.DataFrame(index=[], columns=data.columns) def _run_pipeline(self, pipeline, start_date, chunksize): """ Compute `pipeline`, providing values for at least `start_date`. Produces a DataFrame containing data for days between `start_date` and `end_date`, where `end_date` is defined by: `end_date = min(start_date + chunksize trading days, simulation_end)` Returns ------- (data, valid_until) : tuple (pd.DataFrame, pd.Timestamp) See Also -------- PipelineEngine.run_pipeline """ days = self.trading_environment.trading_days # Load data starting from the previous trading day... start_date_loc = days.get_loc(start_date) # ...continuing until either the day before the simulation end, or # until chunksize days of data have been loaded. sim_end = self.sim_params.last_close.normalize() end_loc = min(start_date_loc + chunksize, days.get_loc(sim_end)) end_date = days[end_loc] return \ self.engine.run_pipeline(pipeline, start_date, end_date), end_date ################## # End Pipeline API ################## @classmethod def all_api_methods(cls): """ Return a list of all the TradingAlgorithm API methods. """ return [ fn for fn in itervalues(vars(cls)) if getattr(fn, 'is_api_method', False) ]