-from ccxt import ExchangeError
import time
-from decimal import Decimal as D
+from datetime import datetime
+from decimal import Decimal as D, ROUND_DOWN
# Put your poloniex api key in market.py
-from market import market
+from json import JSONDecodeError
+from ccxt import ExchangeError, ExchangeNotAvailable
+import requests
+import helper as h
+from store import *
+
+# FIXME: correctly handle web call timeouts
class Portfolio:
URL = "https://cryptoportfolio.io/wp-content/uploads/portfolio/json/cryptoportfolio.json"
data = None
@classmethod
- def repartition_pertenthousand(cls, liquidity="medium"):
+ def repartition(cls, liquidity="medium"):
cls.parse_cryptoportfolio()
liquidities = cls.liquidities[liquidity]
cls.last_date = sorted(liquidities.keys())[-1]
@classmethod
def get_cryptoportfolio(cls):
- import json
- import urllib3
- urllib3.disable_warnings()
- http = urllib3.PoolManager()
-
try:
- r = http.request("GET", cls.URL)
+ r = requests.get(cls.URL)
except Exception:
return
try:
- cls.data = json.loads(r.data,
- parse_int=D,
- parse_float=D)
- except json.JSONDecodeError:
+ cls.data = r.json(parse_int=D, parse_float=D)
+ except JSONDecodeError:
cls.data = None
@classmethod
cls.get_cryptoportfolio()
def filter_weights(weight_hash):
- if weight_hash[1] == 0:
+ if weight_hash[1][0] == 0:
return False
if weight_hash[0] == "_row":
return False
def clean_weights(i):
def clean_weights_(h):
- if type(h[1][i]) == str:
- return [h[0], h[1][i]]
+ if h[0].endswith("s"):
+ return [h[0][0:-1], (h[1][i], "short")]
else:
- return [h[0], int(h[1][i] * 10000)]
+ return [h[0], (h[1][i], "long")]
return clean_weights_
def parse_weights(portfolio_hash):
- # FIXME: we'll need shorts at some point
- assert all(map(lambda x: x == "long", portfolio_hash["holding"]["direction"]))
weights_hash = portfolio_hash["weights"]
weights = {}
for i in range(len(weights_hash["_row"])):
"high": high_liquidity,
}
+class Computation:
+ computations = {
+ "default": lambda x, y: x[y],
+ "average": lambda x, y: x["average"],
+ "bid": lambda x, y: x["bid"],
+ "ask": lambda x, y: x["ask"],
+ }
+
+ @classmethod
+ def compute_value(cls, ticker, action, compute_value="default"):
+ if action == "buy":
+ action = "ask"
+ if action == "sell":
+ action = "bid"
+ if isinstance(compute_value, str):
+ compute_value = cls.computations[compute_value]
+ return compute_value(ticker, action)
+
class Amount:
def __init__(self, currency, value, linked_to=None, ticker=None, rate=None):
self.currency = currency
self.ticker = ticker
self.rate = rate
- self.ticker_cache = {}
- self.ticker_cache_timestamp = time.time()
-
def in_currency(self, other_currency, market, rate=None, action=None, compute_value="average"):
if other_currency == self.currency:
return self
self.value * rate,
linked_to=self,
rate=rate)
- asset_ticker = Trade.get_ticker(self.currency, other_currency, market)
+ asset_ticker = h.get_ticker(self.currency, other_currency, market)
if asset_ticker is not None:
- rate = Trade.compute_value(asset_ticker, action, compute_value=compute_value)
+ rate = Computation.compute_value(asset_ticker, action, compute_value=compute_value)
return Amount(
other_currency,
self.value * rate,
else:
raise Exception("This asset is not available in the chosen market")
+ def __round__(self, n=8):
+ return Amount(self.currency, self.value.quantize(D(1)/D(10**n), rounding=ROUND_DOWN))
+
def __abs__(self):
return Amount(self.currency, abs(self.value))
return self.__add__(other)
def __sub__(self, other):
+ if other == 0:
+ return self
if other.currency != self.currency and other.value * self.value != 0:
raise Exception("Summing amounts must be done with same currencies")
return Amount(self.currency, self.value - other.value)
def __mul__(self, value):
- if type(value) != int and type(value) != float and type(value) != D:
+ if not isinstance(value, (int, float, D)):
raise TypeError("Amount may only be multiplied by numbers")
return Amount(self.currency, self.value * value)
return self.__mul__(value)
def __floordiv__(self, value):
- if type(value) != int and type(value) != float and type(value) != D:
- raise TypeError("Amount may only be multiplied by integers")
+ if not isinstance(value, (int, float, D)):
+ raise TypeError("Amount may only be divided by numbers")
return Amount(self.currency, self.value / value)
def __truediv__(self, value):
return self.__floordiv__(value)
def __lt__(self, other):
+ if other == 0:
+ return self.value < 0
if self.currency != other.currency:
raise Exception("Comparing amounts must be done with same currencies")
return self.value < other.value
+ def __le__(self, other):
+ return self == other or self < other
+
+ def __gt__(self, other):
+ return not self <= other
+
+ def __ge__(self, other):
+ return not self < other
+
def __eq__(self, other):
if other == 0:
return self.value == 0
raise Exception("Comparing amounts must be done with same currencies")
return self.value == other.value
+ def __ne__(self, other):
+ return not self == other
+
+ def __neg__(self):
+ return Amount(self.currency, - self.value)
+
def __str__(self):
if self.linked_to is None:
return "{:.8f} {}".format(self.value, self.currency)
return "Amount({:.8f} {} -> {})".format(self.value, self.currency, repr(self.linked_to))
class Balance:
- known_balances = {}
- def __init__(self, currency, total_value, free_value, used_value):
+ def __init__(self, currency, hash_):
self.currency = currency
- self.total = Amount(currency, total_value)
- self.free = Amount(currency, free_value)
- self.used = Amount(currency, used_value)
-
- @classmethod
- def from_hash(cls, currency, hash_):
- return cls(currency, hash_["total"], hash_["free"], hash_["used"])
-
- @classmethod
- def in_currency(cls, other_currency, market, compute_value="average", type="total"):
- amounts = {}
- for currency in cls.known_balances:
- balance = cls.known_balances[currency]
- other_currency_amount = getattr(balance, type)\
- .in_currency(other_currency, market, compute_value=compute_value)
- amounts[currency] = other_currency_amount
- return amounts
-
- @classmethod
- def currencies(cls):
- return cls.known_balances.keys()
-
- @classmethod
- def _fill_balances(cls, hash_):
- for key in hash_:
- if key in ["info", "free", "used", "total"]:
- continue
- if hash_[key]["total"] > 0 or key in cls.known_balances:
- cls.known_balances[key] = cls.from_hash(key, hash_[key])
-
- @classmethod
- def fetch_balances(cls, market):
- cls._fill_balances(market.fetch_balance())
- return cls.known_balances
-
- @classmethod
- def dispatch_assets(cls, amount, repartition=None):
- if repartition is None:
- repartition = Portfolio.repartition_pertenthousand()
- sum_pertenthousand = sum([v for k, v in repartition.items()])
- amounts = {}
- for currency, ptt in repartition.items():
- amounts[currency] = ptt * amount / sum_pertenthousand
- if currency not in cls.known_balances:
- cls.known_balances[currency] = cls(currency, 0, 0, 0)
- return amounts
-
- @classmethod
- def prepare_trades(cls, market, base_currency="BTC", compute_value="average"):
- cls.fetch_balances(market)
- values_in_base = cls.in_currency(base_currency, market, compute_value=compute_value)
- total_base_value = sum(values_in_base.values())
- new_repartition = cls.dispatch_assets(total_base_value)
- # Recompute it in case we have new currencies
- values_in_base = cls.in_currency(base_currency, market, compute_value=compute_value)
- Trade.compute_trades(values_in_base, new_repartition, market=market)
-
- @classmethod
- def update_trades(cls, market, base_currency="BTC", compute_value="average", only=None):
- cls.fetch_balances(market)
- values_in_base = cls.in_currency(base_currency, market, compute_value=compute_value)
- total_base_value = sum(values_in_base.values())
- new_repartition = cls.dispatch_assets(total_base_value)
- Trade.compute_trades(values_in_base, new_repartition, only=only, market=market)
-
- @classmethod
- def prepare_trades_to_sell_all(cls, market, base_currency="BTC", compute_value="average"):
- cls.fetch_balances(market)
- values_in_base = cls.in_currency(base_currency, market, compute_value=compute_value)
- total_base_value = sum(values_in_base.values())
- new_repartition = cls.dispatch_assets(total_base_value, repartition={ base_currency: 1 })
- Trade.compute_trades(values_in_base, new_repartition, market=market)
+ for key in ["total",
+ "exchange_total", "exchange_used", "exchange_free",
+ "margin_total", "margin_borrowed", "margin_free"]:
+ setattr(self, key, Amount(currency, hash_.get(key, 0)))
+
+ self.margin_position_type = hash_.get("margin_position_type")
+
+ if hash_.get("margin_borrowed_base_currency") is not None:
+ base_currency = hash_["margin_borrowed_base_currency"]
+ for key in [
+ "margin_liquidation_price",
+ "margin_pending_gain",
+ "margin_lending_fees",
+ "margin_borrowed_base_price"
+ ]:
+ setattr(self, key, Amount(base_currency, hash_.get(key, 0)))
def __repr__(self):
- return "Balance({} [{}/{}/{}])".format(self.currency, str(self.free), str(self.used), str(self.total))
+ if self.exchange_total > 0:
+ if self.exchange_free > 0 and self.exchange_used > 0:
+ exchange = " Exch: [✔{} + ❌{} = {}]".format(str(self.exchange_free), str(self.exchange_used), str(self.exchange_total))
+ elif self.exchange_free > 0:
+ exchange = " Exch: [✔{}]".format(str(self.exchange_free))
+ else:
+ exchange = " Exch: [❌{}]".format(str(self.exchange_used))
+ else:
+ exchange = ""
-class Computation:
- computations = {
- "default": lambda x, y: x[y],
- "average": lambda x, y: x["average"],
- "bid": lambda x, y: x["bid"],
- "ask": lambda x, y: x["ask"],
- }
+ if self.margin_total > 0:
+ if self.margin_free != 0 and self.margin_borrowed != 0:
+ margin = " Margin: [✔{} + borrowed {} = {}]".format(str(self.margin_free), str(self.margin_borrowed), str(self.margin_total))
+ elif self.margin_free != 0:
+ margin = " Margin: [✔{}]".format(str(self.margin_free))
+ else:
+ margin = " Margin: [borrowed {}]".format(str(self.margin_borrowed))
+ elif self.margin_total < 0:
+ margin = " Margin: [{} @@ {}/{}]".format(str(self.margin_total),
+ str(self.margin_borrowed_base_price),
+ str(self.margin_lending_fees))
+ else:
+ margin = ""
+ if self.margin_total != 0 and self.exchange_total != 0:
+ total = " Total: [{}]".format(str(self.total))
+ else:
+ total = ""
-class Trade:
- trades = {}
+ return "Balance({}".format(self.currency) + "".join([exchange, margin, total]) + ")"
+class Trade:
def __init__(self, value_from, value_to, currency, market=None):
# We have value_from of currency, and want to finish with value_to of
# that currency. value_* may not be in currency's terms
self.orders = []
self.market = market
assert self.value_from.currency == self.value_to.currency
- assert self.value_from.linked_to is not None and self.value_from.linked_to.currency == self.currency
+ if self.value_from != 0:
+ assert self.value_from.linked_to is not None and self.value_from.linked_to.currency == self.currency
+ elif self.value_from.linked_to is None:
+ self.value_from.linked_to = Amount(self.currency, 0)
self.base_currency = self.value_from.currency
- fees_cache = {}
- @classmethod
- def fetch_fees(cls, market):
- if market.__class__ not in cls.fees_cache:
- cls.fees_cache[market.__class__] = market.fetch_fees()
- return cls.fees_cache[market.__class__]
-
- ticker_cache = {}
- ticker_cache_timestamp = time.time()
- @classmethod
- def get_ticker(cls, c1, c2, market, refresh=False):
- def invert(ticker):
- return {
- "inverted": True,
- "average": (1/ticker["bid"] + 1/ticker["ask"]) / 2,
- "original": ticker,
- }
- def augment_ticker(ticker):
- ticker.update({
- "inverted": False,
- "average": (ticker["bid"] + ticker["ask"] ) / 2,
- })
-
- if time.time() - cls.ticker_cache_timestamp > 5:
- cls.ticker_cache = {}
- cls.ticker_cache_timestamp = time.time()
- elif not refresh:
- if (c1, c2, market.__class__) in cls.ticker_cache:
- return cls.ticker_cache[(c1, c2, market.__class__)]
- if (c2, c1, market.__class__) in cls.ticker_cache:
- return invert(cls.ticker_cache[(c2, c1, market.__class__)])
-
- try:
- cls.ticker_cache[(c1, c2, market.__class__)] = market.fetch_ticker("{}/{}".format(c1, c2))
- augment_ticker(cls.ticker_cache[(c1, c2, market.__class__)])
- except ExchangeError:
- try:
- cls.ticker_cache[(c2, c1, market.__class__)] = market.fetch_ticker("{}/{}".format(c2, c1))
- augment_ticker(cls.ticker_cache[(c2, c1, market.__class__)])
- except ExchangeError:
- cls.ticker_cache[(c1, c2, market.__class__)] = None
- return cls.get_ticker(c1, c2, market)
-
- @classmethod
- def compute_trades(cls, values_in_base, new_repartition, only=None, market=None):
- base_currency = sum(values_in_base.values()).currency
- for currency in Balance.currencies():
- if currency == base_currency:
- continue
- trade = cls(
- values_in_base.get(currency, Amount(base_currency, 0)),
- new_repartition.get(currency, Amount(base_currency, 0)),
- currency,
- market=market
- )
- if only is None or trade.action == only:
- cls.trades[currency] = trade
- return cls.trades
-
- @classmethod
- def prepare_orders(cls, only=None, compute_value="default"):
- for currency, trade in cls.trades.items():
- if only is None or trade.action == only:
- trade.prepare_order(compute_value=compute_value)
-
@property
def action(self):
if self.value_from == self.value_to:
if self.base_currency == self.currency:
return None
- if self.value_from < self.value_to:
+ if abs(self.value_from) < abs(self.value_to):
+ return "acquire"
+ else:
+ return "dispose"
+
+ def order_action(self, inverted):
+ if (self.value_from < self.value_to) != inverted:
return "buy"
else:
return "sell"
- def order_action(self, inverted):
- if self.value_from < self.value_to:
- return "buy" if not inverted else "sell"
+ @property
+ def trade_type(self):
+ if self.value_from + self.value_to < 0:
+ return "short"
else:
- return "sell" if not inverted else "buy"
+ return "long"
+
+ def filled_amount(self, in_base_currency=False):
+ filled_amount = 0
+ for order in self.orders:
+ filled_amount += order.filled_amount(in_base_currency=in_base_currency)
+ return filled_amount
+
+ def update_order(self, order, tick):
+ new_order = None
+ if tick in [0, 1, 3, 4, 6]:
+ print("{}, tick {}, waiting".format(order, tick))
+ elif tick == 2:
+ new_order = self.prepare_order(compute_value=lambda x, y: (x[y] + x["average"]) / 2)
+ print("{}, tick {}, cancelling and adjusting to {}".format(order, tick, new_order))
+ elif tick ==5:
+ new_order = self.prepare_order(compute_value=lambda x, y: (x[y]*2 + x["average"]) / 3)
+ print("{}, tick {}, cancelling and adjusting to {}".format(order, tick, new_order))
+ elif tick >= 7:
+ if tick == 7:
+ print("{}, tick {}, fallbacking to market value".format(order, tick))
+ if (tick - 7) % 3 == 0:
+ new_order = self.prepare_order(compute_value="default")
+ print("{}, tick {}, market value, cancelling and adjusting to {}".format(order, tick, new_order))
+
+ if new_order is not None:
+ order.cancel()
+ new_order.run()
def prepare_order(self, compute_value="default"):
if self.action is None:
- return
- ticker = self.value_from.ticker
+ return None
+ ticker = h.get_ticker(self.currency, self.base_currency, self.market)
inverted = ticker["inverted"]
if inverted:
ticker = ticker["original"]
- rate = Trade.compute_value(ticker, self.order_action(inverted), compute_value=compute_value)
- # 0.1
+ rate = Computation.compute_value(ticker, self.order_action(inverted), compute_value=compute_value)
delta_in_base = abs(self.value_from - self.value_to)
# 9 BTC's worth of move (10 - 1 or 1 - 10 depending on case)
if not inverted:
- if self.action == "sell":
- # I have 10 BTC worth of FOO, and I want to sell 9 BTC worth of it
- # At rate 1 Foo = 0.1 BTC
- value_from = self.value_from.linked_to
- # value_from = 100 FOO
- value_to = self.value_to.in_currency(self.currency, self.market, rate=1/self.value_from.rate)
- # value_to = 10 FOO (1 BTC * 1/0.1)
- delta = abs(value_to - value_from)
- # delta = 90 FOO
- # Action: "sell" "90 FOO" at rate "0.1" "BTC" on "market"
-
- # Note: no rounding error possible: if we have value_to == 0, then delta == value_from
+ base_currency = self.base_currency
+ # BTC
+ if self.action == "dispose":
+ filled = self.filled_amount(in_base_currency=False)
+ delta = delta_in_base.in_currency(self.currency, self.market, rate=1/self.value_from.rate)
+ # I have 10 BTC worth of FOO, and I want to sell 9 BTC
+ # worth of it, computed first with rate 10 FOO = 1 BTC.
+ # -> I "sell" "90" FOO at proposed rate "rate".
+
+ delta = delta - filled
+ # I already sold 60 FOO, 30 left
else:
- delta = delta_in_base.in_currency(self.currency, self.market, rate=1/rate)
- # I want to buy 9 / 0.1 FOO
- # Action: "buy" "90 FOO" at rate "0.1" "BTC" on "market"
+ filled = self.filled_amount(in_base_currency=True)
+ delta = (delta_in_base - filled).in_currency(self.currency, self.market, rate=1/rate)
+ # I want to buy 9 BTC worth of FOO, computed with rate
+ # 10 FOO = 1 BTC
+ # -> I "buy" "9 / rate" FOO at proposed rate "rate"
- # FIXME: Need to round up to the correct amount of FOO in case
- # we want to use all BTC
- currency = self.base_currency
- # BTC
+ # I already bought 3 / rate FOO, 6 / rate left
else:
- if self.action == "sell":
+ base_currency = self.currency
+ # FOO
+ if self.action == "dispose":
+ filled = self.filled_amount(in_base_currency=True)
+ # Base is FOO
+
+ delta = (delta_in_base.in_currency(self.currency, self.market, rate=1/self.value_from.rate)
+ - filled).in_currency(self.base_currency, self.market, rate=1/rate)
# I have 10 BTC worth of FOO, and I want to sell 9 BTC worth of it
- # At rate 1 Foo = 0.1 BTC
- delta = delta_in_base
- # Action: "buy" "9 BTC" at rate "1/0.1" "FOO" on market
+ # computed at rate 1 Foo = 0.01 BTC
+ # Computation says I should sell it at 125 FOO / BTC
+ # -> delta_in_base = 9 BTC
+ # -> delta = (9 * 1/0.01 FOO) * 1/125 = 7.2 BTC
+ # Action: "buy" "7.2 BTC" at rate "125" "FOO" on market
- # FIXME: Need to round up to the correct amount of FOO in case
- # we want to sell all
+ # I already bought 300/125 BTC, only 600/125 left
else:
- delta = delta_in_base
- # I want to buy 9 / 0.1 FOO
- # Action: "sell" "9 BTC" at rate "1/0.1" "FOO" on "market"
-
- # FIXME: Need to round up to the correct amount of FOO in case
- # we want to use all BTC
-
- currency = self.currency
- # FOO
-
- self.orders.append(Order(self.order_action(inverted), delta, rate, currency, self.market))
+ filled = self.filled_amount(in_base_currency=False)
+ # Base is FOO
- @classmethod
- def compute_value(cls, ticker, action, compute_value="default"):
- if type(compute_value) == str:
- compute_value = Computation.computations[compute_value]
- return compute_value(ticker, action)
+ delta = delta_in_base
+ # I have 1 BTC worth of FOO, and I want to buy 9 BTC worth of it
+ # At rate 100 Foo / BTC
+ # Computation says I should buy it at 125 FOO / BTC
+ # -> delta_in_base = 9 BTC
+ # Action: "sell" "9 BTC" at rate "125" "FOO" on market
- @classmethod
- def all_orders(cls, state=None):
- all_orders = sum(map(lambda v: v.orders, cls.trades.values()), [])
- if state is None:
- return all_orders
- else:
- return list(filter(lambda o: o.status == state, all_orders))
+ delta = delta - filled
+ # I already sold 4 BTC, only 5 left
- @classmethod
- def run_orders(cls):
- for order in cls.all_orders(state="pending"):
- order.run()
+ close_if_possible = (self.value_to == 0)
- @classmethod
- def follow_orders(cls, verbose=True, sleep=30):
- orders = cls.all_orders()
- finished_orders = []
- while len(orders) != len(finished_orders):
- time.sleep(sleep)
- for order in orders:
- if order in finished_orders:
- continue
- if order.get_status() != "open":
- finished_orders.append(order)
- if verbose:
- print("finished {}".format(order))
- if verbose:
- print("All orders finished")
+ if delta <= 0:
+ print("Less to do than already filled: {}".format(delta))
+ return None
- @classmethod
- def update_all_orders_status(cls):
- for order in cls.all_orders(state="open"):
- order.get_status()
+ order = Order(self.order_action(inverted),
+ delta, rate, base_currency, self.trade_type,
+ self.market, self, close_if_possible=close_if_possible)
+ self.orders.append(order)
+ return order
def __repr__(self):
return "Trade({} -> {} in {}, {})".format(
self.currency,
self.action)
- @classmethod
- def print_all_with_order(cls):
- for trade in cls.trades.values():
- trade.print_with_order()
-
def print_with_order(self):
print(self)
for order in self.orders:
print("\t", order, sep="")
class Order:
- def __init__(self, action, amount, rate, base_currency, market):
+ def __init__(self, action, amount, rate, base_currency, trade_type, market,
+ trade, close_if_possible=False):
self.action = action
self.amount = amount
self.rate = rate
self.base_currency = base_currency
self.market = market
- self.result = None
+ self.trade_type = trade_type
+ self.results = []
+ self.mouvements = []
self.status = "pending"
+ self.trade = trade
+ self.close_if_possible = close_if_possible
+ self.id = None
+ self.fetch_cache_timestamp = None
def __repr__(self):
- return "Order({} {} at {} {} [{}])".format(
+ return "Order({} {} {} at {} {} [{}]{})".format(
self.action,
+ self.trade_type,
self.amount,
self.rate,
self.base_currency,
- self.status
+ self.status,
+ " ✂" if self.close_if_possible else "",
)
+ @property
+ def account(self):
+ if self.trade_type == "long":
+ return "exchange"
+ else:
+ return "margin"
+
+ @property
+ def open(self):
+ return self.status == "open"
+
@property
def pending(self):
return self.status == "pending"
def finished(self):
return self.status == "closed" or self.status == "canceled" or self.status == "error"
- def run(self, debug=False):
+ def run(self):
symbol = "{}/{}".format(self.amount.currency, self.base_currency)
- amount = self.amount.value
+ amount = round(self.amount, self.market.order_precision(symbol)).value
- if debug:
- print("market.create_order('{}', 'limit', '{}', {}, price={})".format(
- symbol, self.action, amount, self.rate))
+ if TradeStore.debug:
+ print("market.create_order('{}', 'limit', '{}', {}, price={}, account={})".format(
+ symbol, self.action, amount, self.rate, self.account))
+ self.results.append({"debug": True, "id": -1})
else:
try:
- self.result = self.market.create_order(symbol, 'limit', self.action, amount, price=self.rate)
- self.status = "open"
+ self.results.append(self.market.create_order(symbol, 'limit', self.action, amount, price=self.rate, account=self.account))
+ except ExchangeNotAvailable:
+ # Impossible to honor the order (dust amount)
+ self.status = "closed"
+ self.mark_finished_order()
+ return
except Exception as e:
self.status = "error"
- print("error when running market.create_order('{}', 'limit', '{}', {}, price={})".format(
- symbol, self.action, amount, self.rate))
+ print("error when running market.create_order('{}', 'limit', '{}', {}, price={}, account={})".format(
+ symbol, self.action, amount, self.rate, self.account))
self.error_message = str("{}: {}".format(e.__class__.__name__, e))
print(self.error_message)
+ return
+ self.id = self.results[0]["id"]
+ self.status = "open"
def get_status(self):
+ if TradeStore.debug:
+ return self.status
# other states are "closed" and "canceled"
- if self.status == "open":
- result = self.market.fetch_order(self.result['id'])
- self.status = result["status"]
+ if not self.finished:
+ self.fetch()
+ if self.finished:
+ self.mark_finished_order()
return self.status
+ def mark_finished_order(self):
+ if TradeStore.debug:
+ return
+ if self.status == "closed":
+ if self.trade_type == "short" and self.action == "buy" and self.close_if_possible:
+ self.market.close_margin_position(self.amount.currency, self.base_currency)
+
+ def fetch(self, force=False):
+ if TradeStore.debug or (not force and self.fetch_cache_timestamp is not None
+ and time.time() - self.fetch_cache_timestamp < 10):
+ return
+ self.fetch_cache_timestamp = time.time()
+
+ result = self.market.fetch_order(self.id)
+ self.results.append(result)
+
+ self.status = result["status"]
+ # Time at which the order started
+ self.timestamp = result["datetime"]
+ self.fetch_mouvements()
+
+ # FIXME: consider open order with dust remaining as closed
+
+ def dust_amount_remaining(self):
+ return self.remaining_amount() < Amount(self.amount.currency, D("0.001"))
+
+ def remaining_amount(self):
+ if self.status == "open":
+ self.fetch()
+ return self.amount - self.filled_amount()
+
+ def filled_amount(self, in_base_currency=False):
+ if self.status == "open":
+ self.fetch()
+ filled_amount = 0
+ for mouvement in self.mouvements:
+ if in_base_currency:
+ filled_amount += mouvement.total_in_base
+ else:
+ filled_amount += mouvement.total
+ return filled_amount
+
+ def fetch_mouvements(self):
+ try:
+ mouvements = self.market.privatePostReturnOrderTrades({"orderNumber": self.id})
+ except ExchangeError:
+ mouvements = []
+ self.mouvements = []
+
+ for mouvement_hash in mouvements:
+ self.mouvements.append(Mouvement(self.amount.currency,
+ self.base_currency, mouvement_hash))
+
def cancel(self):
- self.market.cancel_order(self.result['id'])
-
-def print_orders(market, base_currency="BTC"):
- Balance.prepare_trades(market, base_currency=base_currency, compute_value="average")
- Trade.prepare_orders(compute_value="average")
- for currency, balance in Balance.known_balances.items():
- print(balance)
- portfolio.Trade.print_all_with_order()
-
-def make_orders(market, base_currency="BTC"):
- Balance.prepare_trades(market, base_currency=base_currency)
- for currency, trade in Trade.trades.items():
- print(trade)
- for order in trade.orders:
- print("\t", order, sep="")
- order.run()
+ if TradeStore.debug:
+ self.status = "canceled"
+ return
+ self.market.cancel_order(self.id)
+ self.fetch()
-if __name__ == '__main__':
- print_orders(market)
+class Mouvement:
+ def __init__(self, currency, base_currency, hash_):
+ self.currency = currency
+ self.base_currency = base_currency
+ self.id = hash_.get("tradeID")
+ self.action = hash_.get("type")
+ self.fee_rate = D(hash_.get("fee", -1))
+ try:
+ self.date = datetime.strptime(hash_.get("date", ""), '%Y-%m-%d %H:%M:%S')
+ except ValueError:
+ self.date = None
+ self.rate = D(hash_.get("rate", 0))
+ self.total = Amount(currency, hash_.get("amount", 0))
+ # rate * total = total_in_base
+ self.total_in_base = Amount(base_currency, hash_.get("total", 0))
+
+if __name__ == '__main__': # pragma: no cover
+ from market import market
+ h.print_orders(market)