Intelegentny_Pszczelarz/.venv/Lib/site-packages/sklearn/linear_model/tests/test_huber.py

# Authors: Manoj Kumar mks542@nyu.edu
# License: BSD 3 clause

import numpy as np
from scipy import optimize, sparse

from sklearn.utils._testing import assert_almost_equal
from sklearn.utils._testing import assert_array_equal
from sklearn.utils._testing import assert_array_almost_equal

from sklearn.datasets import make_regression
from sklearn.linear_model import HuberRegressor, LinearRegression, SGDRegressor, Ridge
from sklearn.linear_model._huber import _huber_loss_and_gradient


def make_regression_with_outliers(n_samples=50, n_features=20):
    rng = np.random.RandomState(0)
    # Generate data with outliers by replacing 10% of the samples with noise.
    X, y = make_regression(
        n_samples=n_samples, n_features=n_features, random_state=0, noise=0.05
    )

    # Replace 10% of the sample with noise.
    num_noise = int(0.1 * n_samples)
    random_samples = rng.randint(0, n_samples, num_noise)
    X[random_samples, :] = 2.0 * rng.normal(0, 1, (num_noise, X.shape[1]))
    return X, y


def test_huber_equals_lr_for_high_epsilon():
    # Test that Ridge matches LinearRegression for large epsilon
    X, y = make_regression_with_outliers()
    lr = LinearRegression()
    lr.fit(X, y)
    huber = HuberRegressor(epsilon=1e3, alpha=0.0)
    huber.fit(X, y)
    assert_almost_equal(huber.coef_, lr.coef_, 3)
    assert_almost_equal(huber.intercept_, lr.intercept_, 2)


def test_huber_max_iter():
    X, y = make_regression_with_outliers()
    huber = HuberRegressor(max_iter=1)
    huber.fit(X, y)
    assert huber.n_iter_ == huber.max_iter


def test_huber_gradient():
    # Test that the gradient calculated by _huber_loss_and_gradient is correct
    rng = np.random.RandomState(1)
    X, y = make_regression_with_outliers()
    sample_weight = rng.randint(1, 3, (y.shape[0]))

    def loss_func(x, *args):
        return _huber_loss_and_gradient(x, *args)[0]

    def grad_func(x, *args):
        return _huber_loss_and_gradient(x, *args)[1]

    # Check using optimize.check_grad that the gradients are equal.
    for _ in range(5):
        # Check for both fit_intercept and otherwise.
        for n_features in [X.shape[1] + 1, X.shape[1] + 2]:
            w = rng.randn(n_features)
            w[-1] = np.abs(w[-1])
            grad_same = optimize.check_grad(
                loss_func, grad_func, w, X, y, 0.01, 0.1, sample_weight
            )
            assert_almost_equal(grad_same, 1e-6, 4)


def test_huber_sample_weights():
    # Test sample_weights implementation in HuberRegressor"""

    X, y = make_regression_with_outliers()
    huber = HuberRegressor()
    huber.fit(X, y)
    huber_coef = huber.coef_
    huber_intercept = huber.intercept_

    # Rescale coefs before comparing with assert_array_almost_equal to make
    # sure that the number of decimal places used is somewhat insensitive to
    # the amplitude of the coefficients and therefore to the scale of the
    # data and the regularization parameter
    scale = max(np.mean(np.abs(huber.coef_)), np.mean(np.abs(huber.intercept_)))

    huber.fit(X, y, sample_weight=np.ones(y.shape[0]))
    assert_array_almost_equal(huber.coef_ / scale, huber_coef / scale)
    assert_array_almost_equal(huber.intercept_ / scale, huber_intercept / scale)

    X, y = make_regression_with_outliers(n_samples=5, n_features=20)
    X_new = np.vstack((X, np.vstack((X[1], X[1], X[3]))))
    y_new = np.concatenate((y, [y[1]], [y[1]], [y[3]]))
    huber.fit(X_new, y_new)
    huber_coef = huber.coef_
    huber_intercept = huber.intercept_
    sample_weight = np.ones(X.shape[0])
    sample_weight[1] = 3
    sample_weight[3] = 2
    huber.fit(X, y, sample_weight=sample_weight)

    assert_array_almost_equal(huber.coef_ / scale, huber_coef / scale)
    assert_array_almost_equal(huber.intercept_ / scale, huber_intercept / scale)

    # Test sparse implementation with sample weights.
    X_csr = sparse.csr_matrix(X)
    huber_sparse = HuberRegressor()
    huber_sparse.fit(X_csr, y, sample_weight=sample_weight)
    assert_array_almost_equal(huber_sparse.coef_ / scale, huber_coef / scale)


def test_huber_sparse():
    X, y = make_regression_with_outliers()
    huber = HuberRegressor(alpha=0.1)
    huber.fit(X, y)

    X_csr = sparse.csr_matrix(X)
    huber_sparse = HuberRegressor(alpha=0.1)
    huber_sparse.fit(X_csr, y)
    assert_array_almost_equal(huber_sparse.coef_, huber.coef_)
    assert_array_equal(huber.outliers_, huber_sparse.outliers_)


def test_huber_scaling_invariant():
    # Test that outliers filtering is scaling independent.
    X, y = make_regression_with_outliers()
    huber = HuberRegressor(fit_intercept=False, alpha=0.0)
    huber.fit(X, y)
    n_outliers_mask_1 = huber.outliers_
    assert not np.all(n_outliers_mask_1)

    huber.fit(X, 2.0 * y)
    n_outliers_mask_2 = huber.outliers_
    assert_array_equal(n_outliers_mask_2, n_outliers_mask_1)

    huber.fit(2.0 * X, 2.0 * y)
    n_outliers_mask_3 = huber.outliers_
    assert_array_equal(n_outliers_mask_3, n_outliers_mask_1)


def test_huber_and_sgd_same_results():
    # Test they should converge to same coefficients for same parameters

    X, y = make_regression_with_outliers(n_samples=10, n_features=2)

    # Fit once to find out the scale parameter. Scale down X and y by scale
    # so that the scale parameter is optimized to 1.0
    huber = HuberRegressor(fit_intercept=False, alpha=0.0, epsilon=1.35)
    huber.fit(X, y)
    X_scale = X / huber.scale_
    y_scale = y / huber.scale_
    huber.fit(X_scale, y_scale)
    assert_almost_equal(huber.scale_, 1.0, 3)

    sgdreg = SGDRegressor(
        alpha=0.0,
        loss="huber",
        shuffle=True,
        random_state=0,
        max_iter=10000,
        fit_intercept=False,
        epsilon=1.35,
        tol=None,
    )
    sgdreg.fit(X_scale, y_scale)
    assert_array_almost_equal(huber.coef_, sgdreg.coef_, 1)


def test_huber_warm_start():
    X, y = make_regression_with_outliers()
    huber_warm = HuberRegressor(alpha=1.0, max_iter=10000, warm_start=True, tol=1e-1)

    huber_warm.fit(X, y)
    huber_warm_coef = huber_warm.coef_.copy()
    huber_warm.fit(X, y)

    # SciPy performs the tol check after doing the coef updates, so
    # these would be almost same but not equal.
    assert_array_almost_equal(huber_warm.coef_, huber_warm_coef, 1)

    assert huber_warm.n_iter_ == 0


def test_huber_better_r2_score():
    # Test that huber returns a better r2 score than non-outliers"""
    X, y = make_regression_with_outliers()
    huber = HuberRegressor(alpha=0.01)
    huber.fit(X, y)
    linear_loss = np.dot(X, huber.coef_) + huber.intercept_ - y
    mask = np.abs(linear_loss) < huber.epsilon * huber.scale_
    huber_score = huber.score(X[mask], y[mask])
    huber_outlier_score = huber.score(X[~mask], y[~mask])

    # The Ridge regressor should be influenced by the outliers and hence
    # give a worse score on the non-outliers as compared to the huber
    # regressor.
    ridge = Ridge(alpha=0.01)
    ridge.fit(X, y)
    ridge_score = ridge.score(X[mask], y[mask])
    ridge_outlier_score = ridge.score(X[~mask], y[~mask])
    assert huber_score > ridge_score

    # The huber model should also fit poorly on the outliers.
    assert ridge_outlier_score > huber_outlier_score


def test_huber_bool():
    # Test that it does not crash with bool data
    X, y = make_regression(n_samples=200, n_features=2, noise=4.0, random_state=0)
    X_bool = X > 0
    HuberRegressor().fit(X_bool, y)
feature: "ANN commit 2" 2023-06-19 00:49:18 +02:00			`# Authors: Manoj Kumar mks542@nyu.edu`
			`# License: BSD 3 clause`

			`import numpy as np`
			`from scipy import optimize, sparse`

			`from sklearn.utils._testing import assert_almost_equal`
			`from sklearn.utils._testing import assert_array_equal`
			`from sklearn.utils._testing import assert_array_almost_equal`

			`from sklearn.datasets import make_regression`
			`from sklearn.linear_model import HuberRegressor, LinearRegression, SGDRegressor, Ridge`
			`from sklearn.linear_model._huber import _huber_loss_and_gradient`


			`def make_regression_with_outliers(n_samples=50, n_features=20):`
			`rng = np.random.RandomState(0)`
			`# Generate data with outliers by replacing 10% of the samples with noise.`
			`X, y = make_regression(`
			`n_samples=n_samples, n_features=n_features, random_state=0, noise=0.05`
			`)`

			`# Replace 10% of the sample with noise.`
			`num_noise = int(0.1 * n_samples)`
			`random_samples = rng.randint(0, n_samples, num_noise)`
			`X[random_samples, :] = 2.0 * rng.normal(0, 1, (num_noise, X.shape[1]))`
			`return X, y`


			`def test_huber_equals_lr_for_high_epsilon():`
			`# Test that Ridge matches LinearRegression for large epsilon`
			`X, y = make_regression_with_outliers()`
			`lr = LinearRegression()`
			`lr.fit(X, y)`
			`huber = HuberRegressor(epsilon=1e3, alpha=0.0)`
			`huber.fit(X, y)`
			`assert_almost_equal(huber.coef_, lr.coef_, 3)`
			`assert_almost_equal(huber.intercept_, lr.intercept_, 2)`


			`def test_huber_max_iter():`
			`X, y = make_regression_with_outliers()`
			`huber = HuberRegressor(max_iter=1)`
			`huber.fit(X, y)`
			`assert huber.n_iter_ == huber.max_iter`


			`def test_huber_gradient():`
			`# Test that the gradient calculated by _huber_loss_and_gradient is correct`
			`rng = np.random.RandomState(1)`
			`X, y = make_regression_with_outliers()`
			`sample_weight = rng.randint(1, 3, (y.shape[0]))`

			`def loss_func(x, *args):`
			`return _huber_loss_and_gradient(x, *args)[0]`

			`def grad_func(x, *args):`
			`return _huber_loss_and_gradient(x, *args)[1]`

			`# Check using optimize.check_grad that the gradients are equal.`
			`for _ in range(5):`
			`# Check for both fit_intercept and otherwise.`
			`for n_features in [X.shape[1] + 1, X.shape[1] + 2]:`
			`w = rng.randn(n_features)`
			`w[-1] = np.abs(w[-1])`
			`grad_same = optimize.check_grad(`
			`loss_func, grad_func, w, X, y, 0.01, 0.1, sample_weight`
			`)`
			`assert_almost_equal(grad_same, 1e-6, 4)`


			`def test_huber_sample_weights():`
			`# Test sample_weights implementation in HuberRegressor"""`

			`X, y = make_regression_with_outliers()`
			`huber = HuberRegressor()`
			`huber.fit(X, y)`
			`huber_coef = huber.coef_`
			`huber_intercept = huber.intercept_`

			`# Rescale coefs before comparing with assert_array_almost_equal to make`
			`# sure that the number of decimal places used is somewhat insensitive to`
			`# the amplitude of the coefficients and therefore to the scale of the`
			`# data and the regularization parameter`
			`scale = max(np.mean(np.abs(huber.coef_)), np.mean(np.abs(huber.intercept_)))`

			`huber.fit(X, y, sample_weight=np.ones(y.shape[0]))`
			`assert_array_almost_equal(huber.coef_ / scale, huber_coef / scale)`
			`assert_array_almost_equal(huber.intercept_ / scale, huber_intercept / scale)`

			`X, y = make_regression_with_outliers(n_samples=5, n_features=20)`
			`X_new = np.vstack((X, np.vstack((X[1], X[1], X[3]))))`
			`y_new = np.concatenate((y, [y[1]], [y[1]], [y[3]]))`
			`huber.fit(X_new, y_new)`
			`huber_coef = huber.coef_`
			`huber_intercept = huber.intercept_`
			`sample_weight = np.ones(X.shape[0])`
			`sample_weight[1] = 3`
			`sample_weight[3] = 2`
			`huber.fit(X, y, sample_weight=sample_weight)`

			`assert_array_almost_equal(huber.coef_ / scale, huber_coef / scale)`
			`assert_array_almost_equal(huber.intercept_ / scale, huber_intercept / scale)`

			`# Test sparse implementation with sample weights.`
			`X_csr = sparse.csr_matrix(X)`
			`huber_sparse = HuberRegressor()`
			`huber_sparse.fit(X_csr, y, sample_weight=sample_weight)`
			`assert_array_almost_equal(huber_sparse.coef_ / scale, huber_coef / scale)`


			`def test_huber_sparse():`
			`X, y = make_regression_with_outliers()`
			`huber = HuberRegressor(alpha=0.1)`
			`huber.fit(X, y)`

			`X_csr = sparse.csr_matrix(X)`
			`huber_sparse = HuberRegressor(alpha=0.1)`
			`huber_sparse.fit(X_csr, y)`
			`assert_array_almost_equal(huber_sparse.coef_, huber.coef_)`
			`assert_array_equal(huber.outliers_, huber_sparse.outliers_)`


			`def test_huber_scaling_invariant():`
			`# Test that outliers filtering is scaling independent.`
			`X, y = make_regression_with_outliers()`
			`huber = HuberRegressor(fit_intercept=False, alpha=0.0)`
			`huber.fit(X, y)`
			`n_outliers_mask_1 = huber.outliers_`
			`assert not np.all(n_outliers_mask_1)`

			`huber.fit(X, 2.0 * y)`
			`n_outliers_mask_2 = huber.outliers_`
			`assert_array_equal(n_outliers_mask_2, n_outliers_mask_1)`

			`huber.fit(2.0 * X, 2.0 * y)`
			`n_outliers_mask_3 = huber.outliers_`
			`assert_array_equal(n_outliers_mask_3, n_outliers_mask_1)`


			`def test_huber_and_sgd_same_results():`
			`# Test they should converge to same coefficients for same parameters`

			`X, y = make_regression_with_outliers(n_samples=10, n_features=2)`

			`# Fit once to find out the scale parameter. Scale down X and y by scale`
			`# so that the scale parameter is optimized to 1.0`
			`huber = HuberRegressor(fit_intercept=False, alpha=0.0, epsilon=1.35)`
			`huber.fit(X, y)`
			`X_scale = X / huber.scale_`
			`y_scale = y / huber.scale_`
			`huber.fit(X_scale, y_scale)`
			`assert_almost_equal(huber.scale_, 1.0, 3)`

			`sgdreg = SGDRegressor(`
			`alpha=0.0,`
			`loss="huber",`
			`shuffle=True,`
			`random_state=0,`
			`max_iter=10000,`
			`fit_intercept=False,`
			`epsilon=1.35,`
			`tol=None,`
			`)`
			`sgdreg.fit(X_scale, y_scale)`
			`assert_array_almost_equal(huber.coef_, sgdreg.coef_, 1)`


			`def test_huber_warm_start():`
			`X, y = make_regression_with_outliers()`
			`huber_warm = HuberRegressor(alpha=1.0, max_iter=10000, warm_start=True, tol=1e-1)`

			`huber_warm.fit(X, y)`
			`huber_warm_coef = huber_warm.coef_.copy()`
			`huber_warm.fit(X, y)`

			`# SciPy performs the tol check after doing the coef updates, so`
			`# these would be almost same but not equal.`
			`assert_array_almost_equal(huber_warm.coef_, huber_warm_coef, 1)`

			`assert huber_warm.n_iter_ == 0`


			`def test_huber_better_r2_score():`
			`# Test that huber returns a better r2 score than non-outliers"""`
			`X, y = make_regression_with_outliers()`
			`huber = HuberRegressor(alpha=0.01)`
			`huber.fit(X, y)`
			`linear_loss = np.dot(X, huber.coef_) + huber.intercept_ - y`
			`mask = np.abs(linear_loss) < huber.epsilon * huber.scale_`
			`huber_score = huber.score(X[mask], y[mask])`
			`huber_outlier_score = huber.score(X[~mask], y[~mask])`

			`# The Ridge regressor should be influenced by the outliers and hence`
			`# give a worse score on the non-outliers as compared to the huber`
			`# regressor.`
			`ridge = Ridge(alpha=0.01)`
			`ridge.fit(X, y)`
			`ridge_score = ridge.score(X[mask], y[mask])`
			`ridge_outlier_score = ridge.score(X[~mask], y[~mask])`
			`assert huber_score > ridge_score`

			`# The huber model should also fit poorly on the outliers.`
			`assert ridge_outlier_score > huber_outlier_score`


			`def test_huber_bool():`
			`# Test that it does not crash with bool data`
			`X, y = make_regression(n_samples=200, n_features=2, noise=4.0, random_state=0)`
			`X_bool = X > 0`
			`HuberRegressor().fit(X_bool, y)`