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import unittest | |
import numpy as np | |
import pandas as pd | |
from pysr import sympy2torch, PySRRegressor | |
# Need to initialize Julia before importing torch... | |
import platform | |
if platform.system() == "Darwin": | |
# Import PyJulia, then Torch | |
from pysr.julia_helpers import init_julia | |
Main = init_julia() | |
import torch | |
else: | |
# Import Torch, then PyJulia | |
# https://github.com/pytorch/pytorch/issues/78829 | |
import torch | |
import sympy | |
class TestTorch(unittest.TestCase): | |
def setUp(self): | |
np.random.seed(0) | |
def test_sympy2torch(self): | |
x, y, z = sympy.symbols("x y z") | |
cosx = 1.0 * sympy.cos(x) + y | |
X = torch.tensor(np.random.randn(1000, 3)) | |
true = 1.0 * torch.cos(X[:, 0]) + X[:, 1] | |
torch_module = sympy2torch(cosx, [x, y, z]) | |
self.assertTrue( | |
np.all(np.isclose(torch_module(X).detach().numpy(), true.detach().numpy())) | |
) | |
def test_pipeline_pandas(self): | |
X = pd.DataFrame(np.random.randn(100, 10)) | |
y = np.ones(X.shape[0]) | |
model = PySRRegressor( | |
progress=False, | |
max_evals=10000, | |
model_selection="accuracy", | |
extra_sympy_mappings={}, | |
output_torch_format=True, | |
) | |
model.fit(X, y) | |
equations = pd.DataFrame( | |
{ | |
"Equation": ["1.0", "cos(x1)", "square(cos(x1))"], | |
"MSE": [1.0, 0.1, 1e-5], | |
"Complexity": [1, 2, 3], | |
} | |
) | |
equations["Complexity MSE Equation".split(" ")].to_csv( | |
"equation_file.csv.bkup", sep="|" | |
) | |
model.refresh(checkpoint_file="equation_file.csv") | |
tformat = model.pytorch() | |
self.assertEqual(str(tformat), "_SingleSymPyModule(expression=cos(x1)**2)") | |
np.testing.assert_almost_equal( | |
tformat(torch.tensor(X.values)).detach().numpy(), | |
np.square(np.cos(X.values[:, 1])), # Selection 1st feature | |
decimal=3, | |
) | |
def test_pipeline(self): | |
X = np.random.randn(100, 10) | |
y = np.ones(X.shape[0]) | |
model = PySRRegressor( | |
progress=False, | |
max_evals=10000, | |
model_selection="accuracy", | |
output_torch_format=True, | |
) | |
model.fit(X, y) | |
equations = pd.DataFrame( | |
{ | |
"Equation": ["1.0", "cos(x1)", "square(cos(x1))"], | |
"MSE": [1.0, 0.1, 1e-5], | |
"Complexity": [1, 2, 3], | |
} | |
) | |
equations["Complexity MSE Equation".split(" ")].to_csv( | |
"equation_file.csv.bkup", sep="|" | |
) | |
model.refresh(checkpoint_file="equation_file.csv") | |
tformat = model.pytorch() | |
self.assertEqual(str(tformat), "_SingleSymPyModule(expression=cos(x1)**2)") | |
np.testing.assert_almost_equal( | |
tformat(torch.tensor(X)).detach().numpy(), | |
np.square(np.cos(X[:, 1])), # 2nd feature | |
decimal=3, | |
) | |
def test_mod_mapping(self): | |
x, y, z = sympy.symbols("x y z") | |
expression = x**2 + sympy.atanh(sympy.Mod(y + 1, 2) - 1) * 3.2 * z | |
module = sympy2torch(expression, [x, y, z]) | |
X = torch.rand(100, 3).float() * 10 | |
true_out = ( | |
X[:, 0] ** 2 + torch.atanh(torch.fmod(X[:, 1] + 1, 2) - 1) * 3.2 * X[:, 2] | |
) | |
torch_out = module(X) | |
np.testing.assert_array_almost_equal( | |
true_out.detach(), torch_out.detach(), decimal=3 | |
) | |
def test_custom_operator(self): | |
X = np.random.randn(100, 3) | |
y = np.ones(X.shape[0]) | |
model = PySRRegressor( | |
progress=False, | |
max_evals=10000, | |
model_selection="accuracy", | |
output_torch_format=True, | |
) | |
model.fit(X, y) | |
equations = pd.DataFrame( | |
{ | |
"Equation": ["1.0", "mycustomoperator(x1)"], | |
"MSE": [1.0, 0.1], | |
"Complexity": [1, 2], | |
} | |
) | |
equations["Complexity MSE Equation".split(" ")].to_csv( | |
"equation_file_custom_operator.csv.bkup", sep="|" | |
) | |
model.set_params( | |
equation_file="equation_file_custom_operator.csv", | |
extra_sympy_mappings={"mycustomoperator": sympy.sin}, | |
extra_torch_mappings={"mycustomoperator": torch.sin}, | |
) | |
model.refresh(checkpoint_file="equation_file_custom_operator.csv") | |
self.assertEqual(str(model.sympy()), "sin(x1)") | |
# Will automatically use the set global state from get_hof. | |
tformat = model.pytorch() | |
self.assertEqual(str(tformat), "_SingleSymPyModule(expression=sin(x1))") | |
np.testing.assert_almost_equal( | |
tformat(torch.tensor(X)).detach().numpy(), | |
np.sin(X[:, 1]), | |
decimal=3, | |
) | |
def test_feature_selection_custom_operators(self): | |
rstate = np.random.RandomState(0) | |
X = pd.DataFrame({f"k{i}": rstate.randn(2000) for i in range(10, 21)}) | |
cos_approx = lambda x: 1 - (x**2) / 2 + (x**4) / 24 + (x**6) / 720 | |
y = X["k15"] ** 2 + 2 * cos_approx(X["k20"]) | |
model = PySRRegressor( | |
progress=False, | |
unary_operators=["cos_approx(x) = 1 - x^2 / 2 + x^4 / 24 + x^6 / 720"], | |
select_k_features=3, | |
maxsize=10, | |
early_stop_condition=1e-5, | |
extra_sympy_mappings={"cos_approx": cos_approx}, | |
extra_torch_mappings={"cos_approx": cos_approx}, | |
random_state=0, | |
deterministic=True, | |
procs=0, | |
multithreading=False, | |
) | |
np.random.seed(0) | |
model.fit(X.values, y.values) | |
torch_module = model.pytorch() | |
np_output = model.predict(X.values) | |
torch_output = torch_module(torch.tensor(X.values)).detach().numpy() | |
np.testing.assert_almost_equal(y.values, np_output, decimal=3) | |
np.testing.assert_almost_equal(y.values, torch_output, decimal=3) | |