def test_custom_objective_min_var():
ef = setup_efficient_frontier()
ef.min_volatility()
built_in = ef.weights
# With custom objective
ef = setup_efficient_frontier()
ef.custom_objective(objective_functions.volatility, ef.cov_matrix, 0)
custom = ef.weights
np.testing.assert_allclose(built_in, custom, atol=1e-7)
def test_max_sharpe_L2_reg_reduces_sharpe():
# L2 reg should reduce the number of small weights at the cost of Sharpe
ef_no_reg = setup_efficient_frontier()
ef_no_reg.max_sharpe()
sharpe_no_reg = ef_no_reg.portfolio_performance()[2]
ef = setup_efficient_frontier()
ef.gamma = 1
ef.max_sharpe()
sharpe = ef.portfolio_performance()[2]
assert sharpe < sharpe_no_reg
def test_clean_weights_short():
ef = setup_efficient_frontier()
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(-1, 1)
)
ef.max_sharpe()
# In practice we would never use such a high cutoff
number_tiny_weights = sum(np.abs(ef.weights) < 0.05)
cleaned = ef.clean_weights(cutoff=0.05)
cleaned_weights = cleaned.values()
clean_number_tiny_weights = sum(abs(i) < 0.05 for i in cleaned_weights)
assert clean_number_tiny_weights == number_tiny_weights
def test_custom_objective_sharpe_L2():
ef = setup_efficient_frontier()
ef.gamma = 2
ef.max_sharpe()
built_in = ef.weights
# With custom objective
ef = setup_efficient_frontier()
ef.custom_objective(objective_functions.negative_sharpe,
ef.expected_returns, ef.cov_matrix, 2)
custom = ef.weights
np.testing.assert_allclose(built_in, custom, atol=1e-7)
def test_bounds_errors():
with pytest.raises(ValueError):
EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(0.06, 1)
)
assert EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(0, 1)
)
with pytest.raises(ValueError):
EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(0.06, 1, 3)
)
def test_efficient_return_many_values():
ef = setup_efficient_frontier()
for target_return in np.arange(0.19, 0.30, 0.01):
ef.efficient_return(target_return)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
mean_return = ef.portfolio_performance()[0]
assert abs(target_return - mean_return) < 0.05
def test_efficient_risk_many_values():
ef = setup_efficient_frontier()
for target_risk in np.arange(0.16, 0.21, 0.01):
ef.efficient_risk(target_risk)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
volatility = ef.portfolio_performance()[1]
assert abs(target_risk - volatility) < 0.05
def test_custom_lower_bound():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(0.02, 1)
)
ef.max_sharpe()
assert ef.weights.min() >= 0.02
np.testing.assert_almost_equal(ef.weights.sum(), 1)
def test_custom_upper_bound():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(0, 0.10)
)
ef.max_sharpe()
ef.portfolio_performance()
assert ef.weights.max() <= 0.1
np.testing.assert_almost_equal(ef.weights.sum(), 1)
def test_clean_weights_error():
ef = setup_efficient_frontier()
ef.max_sharpe()
with pytest.raises(ValueError):
ef.clean_weights(rounding=1.3)
with pytest.raises(ValueError):
ef.clean_weights(rounding=0)
assert ef.clean_weights(rounding=3)
def test_custom_objective_equal_weights():
ef = setup_efficient_frontier()
def new_objective(weights):
return (weights ** 2).sum()
ef.custom_objective(new_objective)
np.testing.assert_allclose(ef.weights, np.array([1 / 20] * 20))
def test_max_sharpe_input_errors():
with pytest.raises(ValueError):
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), gamma="2"
)
with warnings.catch_warnings(record=True) as w:
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), gamma=-1)
assert len(w) == 1
assert issubclass(w[0].category, UserWarning)
assert (
str(w[0].message)
== "in most cases, gamma should be positive"
)
with pytest.raises(ValueError):
ef.max_sharpe(risk_free_rate="0.2")
def test_max_quadratic_utility_market_neutral():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(-1, 1)
)
ef.max_quadratic_utility(market_neutral=True)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
np.testing.assert_allclose(
ef.portfolio_performance(),
(1.248936321062371, 1.0219175004907117, 1.2025787996313317),
)
def test_custom_convex_abs_exposure():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
ef.add_constraint(lambda x: cp.norm(x, 1) <= 2)
ef.convex_objective(
objective_functions.portfolio_variance,
cov_matrix=ef.cov_matrix,
weights_sum_to_one=False,
)
def test_efficient_frontier_error():
ef = setup_efficient_frontier()
with pytest.raises(ValueError):
EfficientFrontier(ef.expected_returns[:-1], ef.cov_matrix)
with pytest.raises(TypeError):
EfficientFrontier(0.02, ef.cov_matrix)
with pytest.raises(ValueError):
EfficientFrontier(ef.expected_returns, None)
with pytest.raises(TypeError):
EfficientFrontier(ef.expected_returns, 0.01)
def test_efficient_return_L2_reg():
ef = setup_efficient_frontier()
ef.add_objective(objective_functions.L2_reg, gamma=1)
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
assert all([i >= 0 for i in w.values()])
np.testing.assert_allclose(ef.portfolio_performance(),
(0.25, 0.20033592447690426, 1.1480716731187948))
def test_efficient_return_market_neutral_warning():
# This fails
ef = setup_efficient_frontier()
with warnings.catch_warnings(record=True) as w:
ef.efficient_return(0.25, market_neutral=True)
assert len(w) == 1
assert issubclass(w[0].category, RuntimeWarning)
assert (str(
w[0].message
) == "Market neutrality requires shorting - bounds have been amended")
def test_efficient_return_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(), (0.25, 0.1682647442258144, 1.3668935881968987)
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_max_sharpe_L2_reg_with_shorts():
ef_no_reg = setup_efficient_frontier()
ef_no_reg.max_sharpe()
initial_number = sum(ef_no_reg.weights > 0.01)
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
ef.add_objective(objective_functions.L2_reg)
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.2995338981166366, 0.2234696161770517, 1.2508810052063901),
)
new_number = sum(ef.weights > 0.01)
assert new_number >= initial_number
def test_max_sharpe_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.4937195216716211, 0.29516576454651955, 1.6049270564945908),
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.max_sharpe()
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_min_volatility_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.min_volatility()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.1516319319875544, 0.1555915367269669, 0.8460095886741129),
)
# Shorting should reduce volatility
volatility = ef.portfolio_performance()[1]
ef_long_only = setup_efficient_frontier()
ef_long_only.min_volatility()
long_only_volatility = ef_long_only.portfolio_performance()[1]
assert volatility < long_only_volatility
def test_efficient_return_market_neutral_warning():
# This fails
ef = setup_efficient_frontier()
with pytest.warns(RuntimeWarning) as w:
ef.efficient_return(0.25, market_neutral=True)
assert len(w) == 1
assert (
str(w[0].message)
== "Market neutrality requires shorting - bounds have been amended"
)
def test_clean_weights_error():
ef = setup_efficient_frontier()
with pytest.raises(AttributeError):
ef.clean_weights()
ef.min_volatility()
with pytest.raises(ValueError):
ef.clean_weights(rounding=1.3)
with pytest.raises(ValueError):
ef.clean_weights(rounding=0)
assert ef.clean_weights(rounding=3)
def test_min_volatility_short():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
w = ef.min_volatility()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.17225673749865328, 0.15559209747801794, 0.9752992044136976),
)
# Shorting should reduce volatility
volatility = ef.portfolio_performance()[1]
ef_long_only = setup_efficient_frontier()
ef_long_only.min_volatility()
long_only_volatility = ef_long_only.portfolio_performance()[1]
assert volatility < long_only_volatility
def test_efficient_return_market_neutral():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(-1, 1)
)
w = ef.efficient_return(0.25, market_neutral=True)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
assert (ef.weights < 1).all() and (ef.weights > -1).all()
np.testing.assert_almost_equal(
ef.portfolio_performance(),
(0.25, 0.20567621957479246, 1.1182624830289896)
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert long_only_sharpe > sharpe
def test_efficient_return_market_neutral():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(-1, 1))
w = ef.efficient_return(0.25, market_neutral=True)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
assert (ef.weights < 1).all() and (ef.weights > -1).all()
np.testing.assert_almost_equal(
ef.portfolio_performance(),
(0.24999999999755498, 0.20567338787141307, 1.1087493060316183),
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert long_only_sharpe > sharpe
def test_max_quadratic_utility_with_shorts():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(-1, 1))
ef.max_quadratic_utility()
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(1.3318330413711252, 1.0198436183533854, 1.2863080356272452),
)
def test_max_sharpe_short():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.40723757138191374, 0.24823079451957306, 1.5524922427959371),
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.max_sharpe()
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_efficient_risk_market_neutral():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(-1, 1))
w = ef.efficient_risk(0.21, market_neutral=True)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
assert (ef.weights < 1).all() and (ef.weights > -1).all()
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.28640632960825885, 0.21, 1.2686015698590967),
atol=1e-6,
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_risk(0.21)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert long_only_sharpe > sharpe
def test_max_sharpe_L2_reg_with_shorts():
ef_no_reg = setup_efficient_frontier()
ef_no_reg.max_sharpe()
initial_number = sum(ef_no_reg.weights > 0.01)
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
ef.gamma = 1
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.32360478341793864, 0.20241509658051923, 1.499911758296975),
)
new_number = sum(ef.weights > 0.01)
assert new_number >= initial_number
def test_max_quadratic_utility_with_shorts():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(-1, 1))
ef.max_quadratic_utility()
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(1.4170505733098597, 1.0438577623242156, 1.3383533884915872),
)
def test_min_volatility_short():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
w = ef.min_volatility()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.1719799152621441, 0.1555954785460613, 0.9767630568850568),
)
# Shorting should reduce volatility
volatility = ef.portfolio_performance()[1]
ef_long_only = setup_efficient_frontier()
ef_long_only.min_volatility()
long_only_volatility = ef_long_only.portfolio_performance()[1]
assert volatility < long_only_volatility
def test_efficient_return_L2_reg():
ef = setup_efficient_frontier()
ef.add_objective(objective_functions.L2_reg, gamma=1)
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
assert all([i >= 0 for i in w.values()])
np.testing.assert_allclose(ef.portfolio_performance(),
(0.25, 0.20961660883459776, 1.0972412981906703))
def test_efficient_risk():
ef = setup_efficient_frontier()
w = ef.efficient_risk(0.19)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(ef.portfolio_performance(),
(0.2857747021087114, 0.19, 1.3988133092245933),
atol=1e-6)
def test_efficient_return():
ef = setup_efficient_frontier()
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(ef.portfolio_performance(),
(0.25, 0.1738877891235972, 1.3226920714748545),
atol=1e-6)
def test_max_sharpe_error():
ef = setup_efficient_frontier()
with pytest.raises(ValueError):
ef.max_sharpe(risk_free_rate="0.02")
# An unsupported constraint type, which is incidentally meaningless.
v = cp.Variable((2, 2), PSD=True)
ef.add_constraint(lambda _: v >> np.zeros((2, 2)))
with pytest.raises(TypeError):
ef.max_sharpe()
def test_ef_plot_utility():
plt.figure()
ef = setup_efficient_frontier()
delta_range = np.arange(0.001, 50, 1)
ax = plotting.plot_efficient_frontier(
ef, ef_param="utility", ef_param_range=delta_range, showfig=False
)
assert len(ax.findobj()) == 125
plt.clf()
plt.close()
def test_efficient_return():
ef = setup_efficient_frontier()
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(), (0.25, 0.17388778912324757, 1.3204920206007777), atol=1e-6
)
def test_efficient_return_market_neutral_warning():
ef = setup_efficient_frontier()
with warnings.catch_warnings(record=True) as w:
ef.efficient_return(0.25, market_neutral=True)
assert len(w) == 1
assert issubclass(w[0].category, RuntimeWarning)
assert (
str(w[0].message)
== "Market neutrality requires shorting - bounds have been amended"
)
def test_efficient_risk():
ef = setup_efficient_frontier()
w = ef.efficient_risk(0.19)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(), (0.2857747021121558, 0.19, 1.396492876), atol=1e-6
)
def test_efficient_return_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(), (0.25, 0.168264744226909, 1.3640929002973508)
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_clean_weights():
ef = setup_efficient_frontier()
ef.max_sharpe()
number_tiny_weights = sum(ef.weights < 1e-4)
cleaned = ef.clean_weights(cutoff=1e-4, rounding=5)
cleaned_weights = cleaned.values()
clean_number_tiny_weights = sum(i < 1e-4 for i in cleaned_weights)
assert clean_number_tiny_weights == number_tiny_weights
# Check rounding
cleaned_weights_str_length = [len(str(i)) for i in cleaned_weights]
assert all([length == 7 or length == 3 for length in cleaned_weights_str_length])
def test_efficient_risk_market_neutral():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(-1, 1)
)
w = ef.efficient_risk(0.19, market_neutral=True)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
assert (ef.weights < 1).all() and (ef.weights > -1).all()
np.testing.assert_almost_equal(
ef.portfolio_performance(),
(0.2309497469661495, 0.19000021138101422, 1.1021245569881066)
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert long_only_sharpe > sharpe
def test_max_sharpe_L2_reg_with_shorts():
ef_no_reg = setup_efficient_frontier()
ef_no_reg.max_sharpe()
initial_number = sum(ef_no_reg.weights > 0.01)
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
ef.gamma = 1
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.3236047844566581, 0.20241509723550233, 1.4969817524033966),
)
new_number = sum(ef.weights > 0.01)
assert new_number >= initial_number
def test_min_volatility_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.min_volatility()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.1719799158957379, 0.15559547854162945, 0.9734986722620801),
)
# Shorting should reduce volatility
volatility = ef.portfolio_performance()[1]
ef_long_only = setup_efficient_frontier()
ef_long_only.min_volatility()
long_only_volatility = ef_long_only.portfolio_performance()[1]
assert volatility < long_only_volatility
def test_constrained_ef_plot_utility():
ef = setup_efficient_frontier()
ef.add_constraint(lambda w: w[0] >= 0.2)
ef.add_constraint(lambda w: w[2] == 0.15)
ef.add_constraint(lambda w: w[3] + w[4] <= 0.10)
delta_range = np.linspace(0.001, 20, 100)
ax = plotting.plot_efficient_frontier(ef,
ef_param_range=delta_range,
showfig=False)
assert len(ax.findobj()) == 125
def test_max_sharpe_risk_free_rate():
ef = setup_efficient_frontier()
ef.max_sharpe()
_, _, initial_sharpe = ef.portfolio_performance()
ef.max_sharpe(risk_free_rate=0.10)
_, _, new_sharpe = ef.portfolio_performance(risk_free_rate=0.10)
assert new_sharpe <= initial_sharpe
ef.max_sharpe(risk_free_rate=0)
_, _, new_sharpe = ef.portfolio_performance(risk_free_rate=0)
assert new_sharpe >= initial_sharpe
def test_efficient_return_L2_reg():
ef = setup_efficient_frontier()
ef.gamma = 1
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
assert all([i >= 0 for i in w.values()])
np.testing.assert_allclose(ef.portfolio_performance(),
(0.25, 0.20032972845476912, 1.1481071819692497))
def test_max_sharpe_risk_free_rate():
ef = setup_efficient_frontier()
ef.max_sharpe()
_, _, initial_sharpe = ef.portfolio_performance()
ef.max_sharpe(risk_free_rate=0.10)
_, _, new_sharpe = ef.portfolio_performance(risk_free_rate=0.10)
assert new_sharpe <= initial_sharpe
ef.max_sharpe(risk_free_rate=0)
_, _, new_sharpe = ef.portfolio_performance(risk_free_rate=0)
assert new_sharpe >= initial_sharpe
def test_efficient_risk_short():
ef = EfficientFrontier(*setup_efficient_frontier(data_only=True),
weight_bounds=(None, None))
w = ef.efficient_risk(0.19)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.30468522897430295, 0.19, 1.4983424153337392),
atol=1e-6,
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_max_sharpe_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.40723757138191374, 0.24823079451957306, 1.5524922427959371),
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.max_sharpe()
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_efficient_risk_sector_constraints_manual():
sector_mapper = {
"GOOG": "tech",
"AAPL": "tech",
"FB": "tech",
"AMZN": "tech",
"BABA": "tech",
"GE": "utility",
"AMD": "tech",
"WMT": "retail",
"BAC": "fig",
"GM": "auto",
"T": "auto",
"UAA": "airline",
"SHLD": "retail",
"XOM": "energy",
"RRC": "energy",
"BBY": "retail",
"MA": "fig",
"PFE": "pharma",
"JPM": "fig",
"SBUX": "retail",
}
sector_upper = {
"tech": 0.2,
"utility": 0.1,
"retail": 0.2,
"fig": 0.4,
"airline": 0.05,
"energy": 0.2,
}
sector_lower = {"utility": 0.01, "fig": 0.02, "airline": 0.01}
ef = setup_efficient_frontier()
for sector in sector_upper:
is_sector = [sector_mapper[t] == sector for t in ef.tickers]
ef.add_constraint(
lambda w: cp.sum(w[is_sector]) <= sector_upper[sector])
for sector in sector_lower:
is_sector = [sector_mapper[t] == sector for t in ef.tickers]
ef.add_constraint(
lambda w: cp.sum(w[is_sector]) >= sector_lower[sector])
weights = ef.efficient_risk(0.19)
for sector in list(set().union(sector_upper, sector_lower)):
sector_sum = 0
for t, v in weights.items():
if sector_mapper[t] == sector:
sector_sum += v
assert sector_sum <= sector_upper.get(sector, 1) + 1e-5
assert sector_sum >= sector_lower.get(sector, 0) - 1e-5
def test_efficient_return_market_neutral():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(-1, 1)
)
w = ef.efficient_return(0.25, market_neutral=True)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 0)
assert (ef.weights < 1).all() and (ef.weights > -1).all()
np.testing.assert_almost_equal(
ef.portfolio_performance(),
(0.25, 0.20567621957041887, 1.1087335497769277)
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert long_only_sharpe > sharpe
def test_min_volatility():
ef = setup_efficient_frontier()
w = ef.min_volatility()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.17915572327783236, 0.1591542642140098, 0.9971057459792518),
)
def test_max_sharpe_long_only():
ef = setup_efficient_frontier()
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.3303554237026972, 0.21671629636481254, 1.4288438866031374),
)
def test_efficient_risk_short():
ef = EfficientFrontier(
*setup_efficient_frontier(data_only=True), weight_bounds=(None, None)
)
w = ef.efficient_risk(0.19)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.30468522897560224, 0.19, 1.4947624032507056),
atol=1e6,
)
sharpe = ef.portfolio_performance()[2]
ef_long_only = setup_efficient_frontier()
ef_long_only.efficient_return(0.25)
long_only_sharpe = ef_long_only.portfolio_performance()[2]
assert sharpe > long_only_sharpe
def test_efficient_return_L2_reg():
ef = setup_efficient_frontier()
ef.gamma = 1
w = ef.efficient_return(0.25)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(), (0.25, 0.20032972838376054, 1.1470454626523598)
)
def test_max_sharpe_L2_reg_many_values():
ef = setup_efficient_frontier()
ef.max_sharpe()
# Count the number of weights more 1%
initial_number = sum(ef.weights > 0.01)
for a in np.arange(0.5, 5, 0.5):
ef.gamma = a
ef.max_sharpe()
np.testing.assert_almost_equal(ef.weights.sum(), 1)
new_number = sum(ef.weights > 0.01)
# Higher gamma should reduce the number of small weights
assert new_number >= initial_number
initial_number = new_number
def test_max_sharpe_L2_reg():
ef = setup_efficient_frontier()
ef.gamma = 1
w = ef.max_sharpe()
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.3062919882686126, 0.20291367026287507, 1.4087639167552641),
)
def test_efficient_return_semicovariance():
df = get_data()
ef = setup_efficient_frontier()
ef.cov_matrix = risk_models.semicovariance(df, benchmark=0)
w = ef.efficient_return(0.12)
assert isinstance(w, dict)
assert set(w.keys()) == set(ef.tickers)
assert set(w.keys()) == set(ef.expected_returns.index)
np.testing.assert_almost_equal(ef.weights.sum(), 1)
np.testing.assert_allclose(
ef.portfolio_performance(),
(0.12000000000871075, 0.06948386214063361, 1.4319423610177537)
)
