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import inspect
import unittest
import numpy as np
from pysr import PySRRegressor
from pysr.sr import run_feature_selection, _handle_feature_selection
from sklearn.utils.estimator_checks import check_estimator
import sympy
import pandas as pd
import warnings
class TestPipeline(unittest.TestCase):
def setUp(self):
# Using inspect,
# get default niterations from PySRRegressor, and double them:
default_niterations = (
inspect.signature(PySRRegressor.__init__).parameters["niterations"].default
)
default_populations = (
inspect.signature(PySRRegressor.__init__).parameters["populations"].default
)
self.default_test_kwargs = dict(
progress=False,
model_selection="accuracy",
niterations=default_niterations * 2,
populations=default_populations * 2,
)
self.rstate = np.random.RandomState(0)
self.X = self.rstate.randn(100, 5)
def test_linear_relation(self):
y = self.X[:, 0]
model = PySRRegressor(
**self.default_test_kwargs,
early_stop_condition="stop_if(loss, complexity) = loss < 1e-4 && complexity == 1",
)
model.fit(self.X, y)
print(model.equations_)
self.assertLessEqual(model.get_best()["loss"], 1e-4)
def test_multiprocessing(self):
y = self.X[:, 0]
model = PySRRegressor(
**self.default_test_kwargs,
procs=2,
multithreading=False,
early_stop_condition="stop_if(loss, complexity) = loss < 1e-4 && complexity == 1",
)
model.fit(self.X, y)
print(model.equations_)
self.assertLessEqual(model.equations_.iloc[-1]["loss"], 1e-4)
def test_multioutput_custom_operator_quiet_custom_complexity(self):
y = self.X[:, [0, 1]] ** 2
model = PySRRegressor(
unary_operators=["square_op(x) = x^2"],
extra_sympy_mappings={"square_op": lambda x: x**2},
complexity_of_operators={"square_op": 2, "plus": 1},
binary_operators=["plus"],
verbosity=0,
**self.default_test_kwargs,
procs=0,
# Test custom operators with constraints:
nested_constraints={"square_op": {"square_op": 3}},
constraints={"square_op": 10},
early_stop_condition="stop_if(loss, complexity) = loss < 1e-4 && complexity == 3",
)
model.fit(self.X, y)
equations = model.equations_
print(equations)
self.assertIn("square_op", model.equations_[0].iloc[-1]["equation"])
self.assertLessEqual(equations[0].iloc[-1]["loss"], 1e-4)
self.assertLessEqual(equations[1].iloc[-1]["loss"], 1e-4)
test_y1 = model.predict(self.X)
test_y2 = model.predict(self.X, index=[-1, -1])
mse1 = np.average((test_y1 - y) ** 2)
mse2 = np.average((test_y2 - y) ** 2)
self.assertLessEqual(mse1, 1e-4)
self.assertLessEqual(mse2, 1e-4)
bad_y = model.predict(self.X, index=[0, 0])
bad_mse = np.average((bad_y - y) ** 2)
self.assertGreater(bad_mse, 1e-4)
def test_multioutput_weighted_with_callable_temp_equation(self):
X = self.X.copy()
y = X[:, [0, 1]] ** 2
w = self.rstate.rand(*y.shape)
w[w < 0.5] = 0.0
w[w >= 0.5] = 1.0
# Double equation when weights are 0:
y = (2 - w) * y
# Thus, pysr needs to use the weights to find the right equation!
model = PySRRegressor(
unary_operators=["sq(x) = x^2"],
binary_operators=["plus"],
extra_sympy_mappings={"sq": lambda x: x**2},
**self.default_test_kwargs,
procs=0,
temp_equation_file=True,
delete_tempfiles=False,
early_stop_condition="stop_if(loss, complexity) = loss < 1e-4 && complexity == 2",
)
model.fit(X.copy(), y, weights=w)
# These tests are flaky, so don't fail test:
try:
np.testing.assert_almost_equal(
model.predict(X.copy())[:, 0], X[:, 0] ** 2, decimal=4
)
except AssertionError:
print("Error in test_multioutput_weighted_with_callable_temp_equation")
print("Model equations: ", model.sympy()[0])
print("True equation: x0^2")
try:
np.testing.assert_almost_equal(
model.predict(X.copy())[:, 1], X[:, 1] ** 2, decimal=4
)
except AssertionError:
print("Error in test_multioutput_weighted_with_callable_temp_equation")
print("Model equations: ", model.sympy()[1])
print("True equation: x1^2")
def test_empty_operators_single_input_warm_start(self):
X = self.rstate.randn(100, 1)
y = X[:, 0] + 3.0
regressor = PySRRegressor(
unary_operators=[],
binary_operators=["plus"],
**self.default_test_kwargs,
early_stop_condition="stop_if(loss, complexity) = loss < 1e-4 && complexity == 3",
)
self.assertTrue("None" in regressor.__repr__())
regressor.fit(X, y)
self.assertTrue("None" not in regressor.__repr__())
self.assertTrue(">>>>" in regressor.__repr__())
self.assertLessEqual(regressor.equations_.iloc[-1]["loss"], 1e-4)
np.testing.assert_almost_equal(regressor.predict(X), y, decimal=1)
# Test if repeated fit works:
regressor.set_params(niterations=0, warm_start=True, early_stop_condition=None)
# This should exit immediately, and use the old equations
regressor.fit(X, y)
self.assertLessEqual(regressor.equations_.iloc[-1]["loss"], 1e-4)
np.testing.assert_almost_equal(regressor.predict(X), y, decimal=1)
# Tweak model selection:
regressor.set_params(model_selection="best")
self.assertEqual(regressor.get_params()["model_selection"], "best")
self.assertTrue("None" not in regressor.__repr__())
self.assertTrue(">>>>" in regressor.__repr__())
def test_noisy(self):
y = self.X[:, [0, 1]] ** 2 + self.rstate.randn(self.X.shape[0], 1) * 0.05
model = PySRRegressor(
# Test that passing a single operator works:
unary_operators="sq(x) = x^2",
binary_operators="plus",
extra_sympy_mappings={"sq": lambda x: x**2},
**{
k: v
for k, v in self.default_test_kwargs.items()
if k != "model_selection"
},
procs=0,
denoise=True,
early_stop_condition="stop_if(loss, complexity) = loss < 0.05 && complexity == 2",
model_selection="best",
)
model.fit(self.X, y)
print(model)
self.assertLessEqual(model.get_best()[1]["loss"], 1e-2)
self.assertLessEqual(model.get_best()[1]["loss"], 1e-2)
def test_pandas_resample_with_nested_constraints(self):
X = pd.DataFrame(
{
"T": self.rstate.randn(500),
"x": self.rstate.randn(500),
"unused_feature": self.rstate.randn(500),
}
)
true_fn = lambda x: np.array(x["T"] + x["x"] ** 2 + 1.323837)
y = true_fn(X)
noise = self.rstate.randn(500) * 0.01
y = y + noise
# We also test y as a pandas array:
y = pd.Series(y)
# Resampled array is a different order of features:
Xresampled = pd.DataFrame(
{
"unused_feature": self.rstate.randn(100),
"x": self.rstate.randn(100),
"T": self.rstate.randn(100),
}
)
model = PySRRegressor(
unary_operators=[],
binary_operators=["+", "*", "/", "-"],
**self.default_test_kwargs,
denoise=True,
nested_constraints={"/": {"+": 1, "-": 1}, "+": {"*": 4}},
early_stop_condition="stop_if(loss, complexity) = loss < 1e-3 && complexity == 7",
)
model.fit(X, y, Xresampled=Xresampled)
self.assertNotIn("unused_feature", model.latex())
self.assertIn("T", model.latex())
self.assertIn("x", model.latex())
self.assertLessEqual(model.get_best()["loss"], 1e-1)
fn = model.get_best()["lambda_format"]
X2 = pd.DataFrame(
{
"T": self.rstate.randn(100),
"unused_feature": self.rstate.randn(100),
"x": self.rstate.randn(100),
}
)
self.assertLess(np.average((fn(X2) - true_fn(X2)) ** 2), 1e-1)
self.assertLess(np.average((model.predict(X2) - true_fn(X2)) ** 2), 1e-1)
def test_high_dim_selection_early_stop(self):
X = pd.DataFrame({f"k{i}": self.rstate.randn(10000) for i in range(10)})
Xresampled = pd.DataFrame({f"k{i}": self.rstate.randn(100) for i in range(10)})
y = X["k7"] ** 2 + np.cos(X["k9"]) * 3
model = PySRRegressor(
unary_operators=["cos"],
select_k_features=3,
early_stop_condition=1e-4, # Stop once most accurate equation is <1e-4 MSE
maxsize=12,
**self.default_test_kwargs,
)
model.set_params(model_selection="accuracy")
model.fit(X, y, Xresampled=Xresampled)
self.assertLess(np.average((model.predict(X) - y) ** 2), 1e-4)
# Again, but with numpy arrays:
model.fit(X.values, y.values, Xresampled=Xresampled.values)
self.assertLess(np.average((model.predict(X.values) - y.values) ** 2), 1e-4)
class TestBest(unittest.TestCase):
def setUp(self):
self.rstate = np.random.RandomState(0)
self.X = self.rstate.randn(10, 2)
self.y = np.cos(self.X[:, 0]) ** 2
self.model = PySRRegressor(
progress=False,
niterations=1,
extra_sympy_mappings={},
output_jax_format=False,
model_selection="accuracy",
equation_file="equation_file.csv",
)
self.model.fit(self.X, self.y)
equations = pd.DataFrame(
{
"equation": ["1.0", "cos(x0)", "square(cos(x0))"],
"loss": [1.0, 0.1, 1e-5],
"complexity": [1, 2, 3],
}
)
equations["complexity loss equation".split(" ")].to_csv(
"equation_file.csv.bkup", sep="|"
)
self.model.refresh()
self.equations_ = self.model.equations_
def test_best(self):
self.assertEqual(self.model.sympy(), sympy.cos(sympy.Symbol("x0")) ** 2)
def test_index_selection(self):
self.assertEqual(self.model.sympy(-1), sympy.cos(sympy.Symbol("x0")) ** 2)
self.assertEqual(self.model.sympy(2), sympy.cos(sympy.Symbol("x0")) ** 2)
self.assertEqual(self.model.sympy(1), sympy.cos(sympy.Symbol("x0")))
self.assertEqual(self.model.sympy(0), 1.0)
def test_best_tex(self):
self.assertEqual(self.model.latex(), "\\cos^{2}{\\left(x_{0} \\right)}")
def test_best_lambda(self):
X = self.X
y = self.y
for f in [self.model.predict, self.equations_.iloc[-1]["lambda_format"]]:
np.testing.assert_almost_equal(f(X), y, decimal=4)
class TestFeatureSelection(unittest.TestCase):
def setUp(self):
self.rstate = np.random.RandomState(0)
def test_feature_selection(self):
X = self.rstate.randn(20000, 5)
y = X[:, 2] ** 2 + X[:, 3] ** 2
selected = run_feature_selection(X, y, select_k_features=2)
self.assertEqual(sorted(selected), [2, 3])
def test_feature_selection_handler(self):
X = self.rstate.randn(20000, 5)
y = X[:, 2] ** 2 + X[:, 3] ** 2
var_names = [f"x{i}" for i in range(5)]
selected_X, selection = _handle_feature_selection(
X,
select_k_features=2,
variable_names=var_names,
y=y,
)
self.assertTrue((2 in selection) and (3 in selection))
selected_var_names = [var_names[i] for i in selection]
self.assertEqual(set(selected_var_names), set("x2 x3".split(" ")))
np.testing.assert_array_equal(
np.sort(selected_X, axis=1), np.sort(X[:, [2, 3]], axis=1)
)
class TestMiscellaneous(unittest.TestCase):
"""Test miscellaneous functions."""
def setUp(self):
# Allows all scikit-learn exception messages to be read.
self.maxDiff = None
def test_deprecation(self):
"""Ensure that deprecation works as expected.
This should give a warning, and sets the correct value.
"""
with self.assertWarns(FutureWarning):
model = PySRRegressor(fractionReplaced=0.2)
# This is a deprecated parameter, so we should get a warning.
# The correct value should be set:
self.assertEqual(model.fraction_replaced, 0.2)
def test_size_warning(self):
"""Ensure that a warning is given for a large input size."""
model = PySRRegressor(max_evals=10000, populations=2)
X = np.random.randn(10001, 2)
y = np.random.randn(10001)
with warnings.catch_warnings():
warnings.simplefilter("error")
with self.assertRaises(Exception) as context:
model.fit(X, y)
self.assertIn("more than 10,000", str(context.exception))
def test_feature_warning(self):
"""Ensure that a warning is given for large number of features."""
model = PySRRegressor()
X = np.random.randn(100, 10)
y = np.random.randn(100)
with warnings.catch_warnings():
warnings.simplefilter("error")
with self.assertRaises(Exception) as context:
model.fit(X, y)
self.assertIn("with 10 features or more", str(context.exception))
def test_scikit_learn_compatibility(self):
"""Test PySRRegressor compatibility with scikit-learn."""
model = PySRRegressor(
max_evals=1000,
verbosity=0,
progress=False,
random_state=0,
deterministic=True,
procs=0,
multithreading=False,
warm_start=False,
) # Return early.
check_generator = check_estimator(model, generate_only=True)
exception_messages = []
for (_, check) in check_generator:
try:
with warnings.catch_warnings():
warnings.simplefilter("ignore")
# To ensure an equation file is written for each output in
# nout, set stop condition to niterations=1
if check.func.__name__ == "check_regressor_multioutput":
model.set_params(niterations=1, max_evals=None)
else:
model.set_params(max_evals=10000)
check(model)
print("Passed", check.func.__name__)
except Exception as e:
error_message = str(e)
exception_messages.append(f"{check.func.__name__}: {error_message}\n")
print("Failed", check.func.__name__, "with:")
# Add a leading tab to error message, which
# might be multi-line:
print("\n".join([(" " * 4) + row for row in error_message.split("\n")]))
# If any checks failed don't let the test pass.
self.assertEqual([], exception_messages)
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