# Authors: The scikit-learn developers # SPDX-License-Identifier: BSD-3-Clause """ Generalized Linear Models with Exponential Dispersion Family """ from numbers import Integral, Real import numpy as np import scipy.optimize from ..._loss.loss import ( HalfGammaLoss, HalfPoissonLoss, HalfSquaredError, HalfTweedieLoss, HalfTweedieLossIdentity, ) from ...base import BaseEstimator, RegressorMixin, _fit_context from ...utils import check_array from ...utils._openmp_helpers import _openmp_effective_n_threads from ...utils._param_validation import Hidden, Interval, StrOptions from ...utils.optimize import _check_optimize_result from ...utils.validation import _check_sample_weight, check_is_fitted from .._linear_loss import LinearModelLoss from ._newton_solver import NewtonCholeskySolver, NewtonSolver class _GeneralizedLinearRegressor(RegressorMixin, BaseEstimator): """Regression via a penalized Generalized Linear Model (GLM). GLMs based on a reproductive Exponential Dispersion Model (EDM) aim at fitting and predicting the mean of the target y as y_pred=h(X*w) with coefficients w. Therefore, the fit minimizes the following objective function with L2 priors as regularizer:: 1/(2*sum(s_i)) * sum(s_i * deviance(y_i, h(x_i*w)) + 1/2 * alpha * ||w||_2^2 with inverse link function h, s=sample_weight and per observation (unit) deviance deviance(y_i, h(x_i*w)). Note that for an EDM, 1/2 * deviance is the negative log-likelihood up to a constant (in w) term. The parameter ``alpha`` corresponds to the lambda parameter in glmnet. Instead of implementing the EDM family and a link function separately, we directly use the loss functions `from sklearn._loss` which have the link functions included in them for performance reasons. We pick the loss functions that implement (1/2 times) EDM deviances. Read more in the :ref:`User Guide `. .. versionadded:: 0.23 Parameters ---------- alpha : float, default=1 Constant that multiplies the penalty term and thus determines the regularization strength. ``alpha = 0`` is equivalent to unpenalized GLMs. In this case, the design matrix `X` must have full column rank (no collinearities). Values must be in the range `[0.0, inf)`. fit_intercept : bool, default=True Specifies if a constant (a.k.a. bias or intercept) should be added to the linear predictor (X @ coef + intercept). solver : {'lbfgs', 'newton-cholesky'}, default='lbfgs' Algorithm to use in the optimization problem: 'lbfgs' Calls scipy's L-BFGS-B optimizer. 'newton-cholesky' Uses Newton-Raphson steps (in arbitrary precision arithmetic equivalent to iterated reweighted least squares) with an inner Cholesky based solver. This solver is a good choice for `n_samples` >> `n_features`, especially with one-hot encoded categorical features with rare categories. Be aware that the memory usage of this solver has a quadratic dependency on `n_features` because it explicitly computes the Hessian matrix. .. versionadded:: 1.2 max_iter : int, default=100 The maximal number of iterations for the solver. Values must be in the range `[1, inf)`. tol : float, default=1e-4 Stopping criterion. For the lbfgs solver, the iteration will stop when ``max{|g_j|, j = 1, ..., d} <= tol`` where ``g_j`` is the j-th component of the gradient (derivative) of the objective function. Values must be in the range `(0.0, inf)`. warm_start : bool, default=False If set to ``True``, reuse the solution of the previous call to ``fit`` as initialization for ``coef_`` and ``intercept_``. verbose : int, default=0 For the lbfgs solver set verbose to any positive number for verbosity. Values must be in the range `[0, inf)`. Attributes ---------- coef_ : array of shape (n_features,) Estimated coefficients for the linear predictor (`X @ coef_ + intercept_`) in the GLM. intercept_ : float Intercept (a.k.a. bias) added to linear predictor. n_iter_ : int Actual number of iterations used in the solver. _base_loss : BaseLoss, default=HalfSquaredError() This is set during fit via `self._get_loss()`. A `_base_loss` contains a specific loss function as well as the link function. The loss to be minimized specifies the distributional assumption of the GLM, i.e. the distribution from the EDM. Here are some examples: ======================= ======== ========================== _base_loss Link Target Domain ======================= ======== ========================== HalfSquaredError identity y any real number HalfPoissonLoss log 0 <= y HalfGammaLoss log 0 < y HalfTweedieLoss log dependent on tweedie power HalfTweedieLossIdentity identity dependent on tweedie power ======================= ======== ========================== The link function of the GLM, i.e. mapping from linear predictor `X @ coeff + intercept` to prediction `y_pred`. For instance, with a log link, we have `y_pred = exp(X @ coeff + intercept)`. """ # We allow for NewtonSolver classes for the "solver" parameter but do not # make them public in the docstrings. This facilitates testing and # benchmarking. _parameter_constraints: dict = { "alpha": [Interval(Real, 0.0, None, closed="left")], "fit_intercept": ["boolean"], "solver": [ StrOptions({"lbfgs", "newton-cholesky"}), Hidden(type), ], "max_iter": [Interval(Integral, 1, None, closed="left")], "tol": [Interval(Real, 0.0, None, closed="neither")], "warm_start": ["boolean"], "verbose": ["verbose"], } def __init__( self, *, alpha=1.0, fit_intercept=True, solver="lbfgs", max_iter=100, tol=1e-4, warm_start=False, verbose=0, ): self.alpha = alpha self.fit_intercept = fit_intercept self.solver = solver self.max_iter = max_iter self.tol = tol self.warm_start = warm_start self.verbose = verbose @_fit_context(prefer_skip_nested_validation=True) def fit(self, X, y, sample_weight=None): """Fit a Generalized Linear Model. Parameters ---------- X : {array-like, sparse matrix} of shape (n_samples, n_features) Training data. y : array-like of shape (n_samples,) Target values. sample_weight : array-like of shape (n_samples,), default=None Sample weights. Returns ------- self : object Fitted model. """ X, y = self._validate_data( X, y, accept_sparse=["csc", "csr"], dtype=[np.float64, np.float32], y_numeric=True, multi_output=False, ) # required by losses if self.solver == "lbfgs": # lbfgs will force coef and therefore raw_prediction to be float64. The # base_loss needs y, X @ coef and sample_weight all of same dtype # (and contiguous). loss_dtype = np.float64 else: loss_dtype = min(max(y.dtype, X.dtype), np.float64) y = check_array(y, dtype=loss_dtype, order="C", ensure_2d=False) if sample_weight is not None: # Note that _check_sample_weight calls check_array(order="C") required by # losses. sample_weight = _check_sample_weight(sample_weight, X, dtype=loss_dtype) n_samples, n_features = X.shape self._base_loss = self._get_loss() linear_loss = LinearModelLoss( base_loss=self._base_loss, fit_intercept=self.fit_intercept, ) if not linear_loss.base_loss.in_y_true_range(y): raise ValueError( "Some value(s) of y are out of the valid range of the loss" f" {self._base_loss.__class__.__name__!r}." ) # TODO: if alpha=0 check that X is not rank deficient # NOTE: Rescaling of sample_weight: # We want to minimize # obj = 1/(2 * sum(sample_weight)) * sum(sample_weight * deviance) # + 1/2 * alpha * L2, # with # deviance = 2 * loss. # The objective is invariant to multiplying sample_weight by a constant. We # could choose this constant such that sum(sample_weight) = 1 in order to end # up with # obj = sum(sample_weight * loss) + 1/2 * alpha * L2. # But LinearModelLoss.loss() already computes # average(loss, weights=sample_weight) # Thus, without rescaling, we have # obj = LinearModelLoss.loss(...) if self.warm_start and hasattr(self, "coef_"): if self.fit_intercept: # LinearModelLoss needs intercept at the end of coefficient array. coef = np.concatenate((self.coef_, np.array([self.intercept_]))) else: coef = self.coef_ coef = coef.astype(loss_dtype, copy=False) else: coef = linear_loss.init_zero_coef(X, dtype=loss_dtype) if self.fit_intercept: coef[-1] = linear_loss.base_loss.link.link( np.average(y, weights=sample_weight) ) l2_reg_strength = self.alpha n_threads = _openmp_effective_n_threads() # Algorithms for optimization: # Note again that our losses implement 1/2 * deviance. if self.solver == "lbfgs": func = linear_loss.loss_gradient opt_res = scipy.optimize.minimize( func, coef, method="L-BFGS-B", jac=True, options={ "maxiter": self.max_iter, "maxls": 50, # default is 20 "iprint": self.verbose - 1, "gtol": self.tol, # The constant 64 was found empirically to pass the test suite. # The point is that ftol is very small, but a bit larger than # machine precision for float64, which is the dtype used by lbfgs. "ftol": 64 * np.finfo(float).eps, }, args=(X, y, sample_weight, l2_reg_strength, n_threads), ) self.n_iter_ = _check_optimize_result("lbfgs", opt_res) coef = opt_res.x elif self.solver == "newton-cholesky": sol = NewtonCholeskySolver( coef=coef, linear_loss=linear_loss, l2_reg_strength=l2_reg_strength, tol=self.tol, max_iter=self.max_iter, n_threads=n_threads, verbose=self.verbose, ) coef = sol.solve(X, y, sample_weight) self.n_iter_ = sol.iteration elif issubclass(self.solver, NewtonSolver): sol = self.solver( coef=coef, linear_loss=linear_loss, l2_reg_strength=l2_reg_strength, tol=self.tol, max_iter=self.max_iter, n_threads=n_threads, ) coef = sol.solve(X, y, sample_weight) self.n_iter_ = sol.iteration else: raise ValueError(f"Invalid solver={self.solver}.") if self.fit_intercept: self.intercept_ = coef[-1] self.coef_ = coef[:-1] else: # set intercept to zero as the other linear models do self.intercept_ = 0.0 self.coef_ = coef return self def _linear_predictor(self, X): """Compute the linear_predictor = `X @ coef_ + intercept_`. Note that we often use the term raw_prediction instead of linear predictor. Parameters ---------- X : {array-like, sparse matrix} of shape (n_samples, n_features) Samples. Returns ------- y_pred : array of shape (n_samples,) Returns predicted values of linear predictor. """ check_is_fitted(self) X = self._validate_data( X, accept_sparse=["csr", "csc", "coo"], dtype=[np.float64, np.float32], ensure_2d=True, allow_nd=False, reset=False, ) return X @ self.coef_ + self.intercept_ def predict(self, X): """Predict using GLM with feature matrix X. Parameters ---------- X : {array-like, sparse matrix} of shape (n_samples, n_features) Samples. Returns ------- y_pred : array of shape (n_samples,) Returns predicted values. """ # check_array is done in _linear_predictor raw_prediction = self._linear_predictor(X) y_pred = self._base_loss.link.inverse(raw_prediction) return y_pred def score(self, X, y, sample_weight=None): """Compute D^2, the percentage of deviance explained. D^2 is a generalization of the coefficient of determination R^2. R^2 uses squared error and D^2 uses the deviance of this GLM, see the :ref:`User Guide `. D^2 is defined as :math:`D^2 = 1-\\frac{D(y_{true},y_{pred})}{D_{null}}`, :math:`D_{null}` is the null deviance, i.e. the deviance of a model with intercept alone, which corresponds to :math:`y_{pred} = \\bar{y}`. The mean :math:`\\bar{y}` is averaged by sample_weight. Best possible score is 1.0 and it can be negative (because the model can be arbitrarily worse). Parameters ---------- X : {array-like, sparse matrix} of shape (n_samples, n_features) Test samples. y : array-like of shape (n_samples,) True values of target. sample_weight : array-like of shape (n_samples,), default=None Sample weights. Returns ------- score : float D^2 of self.predict(X) w.r.t. y. """ # TODO: Adapt link to User Guide in the docstring, once # https://github.com/scikit-learn/scikit-learn/pull/22118 is merged. # # Note, default score defined in RegressorMixin is R^2 score. # TODO: make D^2 a score function in module metrics (and thereby get # input validation and so on) raw_prediction = self._linear_predictor(X) # validates X # required by losses y = check_array(y, dtype=raw_prediction.dtype, order="C", ensure_2d=False) if sample_weight is not None: # Note that _check_sample_weight calls check_array(order="C") required by # losses. sample_weight = _check_sample_weight(sample_weight, X, dtype=y.dtype) base_loss = self._base_loss if not base_loss.in_y_true_range(y): raise ValueError( "Some value(s) of y are out of the valid range of the loss" f" {base_loss.__name__}." ) constant = np.average( base_loss.constant_to_optimal_zero(y_true=y, sample_weight=None), weights=sample_weight, ) # Missing factor of 2 in deviance cancels out. deviance = base_loss( y_true=y, raw_prediction=raw_prediction, sample_weight=sample_weight, n_threads=1, ) y_mean = base_loss.link.link(np.average(y, weights=sample_weight)) deviance_null = base_loss( y_true=y, raw_prediction=np.tile(y_mean, y.shape[0]), sample_weight=sample_weight, n_threads=1, ) return 1 - (deviance + constant) / (deviance_null + constant) def _more_tags(self): try: # Create instance of BaseLoss if fit wasn't called yet. This is necessary as # TweedieRegressor might set the used loss during fit different from # self._base_loss. base_loss = self._get_loss() return {"requires_positive_y": not base_loss.in_y_true_range(-1.0)} except (ValueError, AttributeError, TypeError): # This happens when the link or power parameter of TweedieRegressor is # invalid. We fallback on the default tags in that case. return {} def _get_loss(self): """This is only necessary because of the link and power arguments of the TweedieRegressor. Note that we do not need to pass sample_weight to the loss class as this is only needed to set loss.constant_hessian on which GLMs do not rely. """ return HalfSquaredError() class PoissonRegressor(_GeneralizedLinearRegressor): """Generalized Linear Model with a Poisson distribution. This regressor uses the 'log' link function. Read more in the :ref:`User Guide `. .. versionadded:: 0.23 Parameters ---------- alpha : float, default=1 Constant that multiplies the L2 penalty term and determines the regularization strength. ``alpha = 0`` is equivalent to unpenalized GLMs. In this case, the design matrix `X` must have full column rank (no collinearities). Values of `alpha` must be in the range `[0.0, inf)`. fit_intercept : bool, default=True Specifies if a constant (a.k.a. bias or intercept) should be added to the linear predictor (`X @ coef + intercept`). solver : {'lbfgs', 'newton-cholesky'}, default='lbfgs' Algorithm to use in the optimization problem: 'lbfgs' Calls scipy's L-BFGS-B optimizer. 'newton-cholesky' Uses Newton-Raphson steps (in arbitrary precision arithmetic equivalent to iterated reweighted least squares) with an inner Cholesky based solver. This solver is a good choice for `n_samples` >> `n_features`, especially with one-hot encoded categorical features with rare categories. Be aware that the memory usage of this solver has a quadratic dependency on `n_features` because it explicitly computes the Hessian matrix. .. versionadded:: 1.2 max_iter : int, default=100 The maximal number of iterations for the solver. Values must be in the range `[1, inf)`. tol : float, default=1e-4 Stopping criterion. For the lbfgs solver, the iteration will stop when ``max{|g_j|, j = 1, ..., d} <= tol`` where ``g_j`` is the j-th component of the gradient (derivative) of the objective function. Values must be in the range `(0.0, inf)`. warm_start : bool, default=False If set to ``True``, reuse the solution of the previous call to ``fit`` as initialization for ``coef_`` and ``intercept_`` . verbose : int, default=0 For the lbfgs solver set verbose to any positive number for verbosity. Values must be in the range `[0, inf)`. Attributes ---------- coef_ : array of shape (n_features,) Estimated coefficients for the linear predictor (`X @ coef_ + intercept_`) in the GLM. intercept_ : float Intercept (a.k.a. bias) added to linear predictor. n_features_in_ : int Number of features seen during :term:`fit`. .. versionadded:: 0.24 feature_names_in_ : ndarray of shape (`n_features_in_`,) Names of features seen during :term:`fit`. Defined only when `X` has feature names that are all strings. .. versionadded:: 1.0 n_iter_ : int Actual number of iterations used in the solver. See Also -------- TweedieRegressor : Generalized Linear Model with a Tweedie distribution. Examples -------- >>> from sklearn import linear_model >>> clf = linear_model.PoissonRegressor() >>> X = [[1, 2], [2, 3], [3, 4], [4, 3]] >>> y = [12, 17, 22, 21] >>> clf.fit(X, y) PoissonRegressor() >>> clf.score(X, y) 0.990... >>> clf.coef_ array([0.121..., 0.158...]) >>> clf.intercept_ 2.088... >>> clf.predict([[1, 1], [3, 4]]) array([10.676..., 21.875...]) """ _parameter_constraints: dict = { **_GeneralizedLinearRegressor._parameter_constraints } def __init__( self, *, alpha=1.0, fit_intercept=True, solver="lbfgs", max_iter=100, tol=1e-4, warm_start=False, verbose=0, ): super().__init__( alpha=alpha, fit_intercept=fit_intercept, solver=solver, max_iter=max_iter, tol=tol, warm_start=warm_start, verbose=verbose, ) def _get_loss(self): return HalfPoissonLoss() class GammaRegressor(_GeneralizedLinearRegressor): """Generalized Linear Model with a Gamma distribution. This regressor uses the 'log' link function. Read more in the :ref:`User Guide `. .. versionadded:: 0.23 Parameters ---------- alpha : float, default=1 Constant that multiplies the L2 penalty term and determines the regularization strength. ``alpha = 0`` is equivalent to unpenalized GLMs. In this case, the design matrix `X` must have full column rank (no collinearities). Values of `alpha` must be in the range `[0.0, inf)`. fit_intercept : bool, default=True Specifies if a constant (a.k.a. bias or intercept) should be added to the linear predictor `X @ coef_ + intercept_`. solver : {'lbfgs', 'newton-cholesky'}, default='lbfgs' Algorithm to use in the optimization problem: 'lbfgs' Calls scipy's L-BFGS-B optimizer. 'newton-cholesky' Uses Newton-Raphson steps (in arbitrary precision arithmetic equivalent to iterated reweighted least squares) with an inner Cholesky based solver. This solver is a good choice for `n_samples` >> `n_features`, especially with one-hot encoded categorical features with rare categories. Be aware that the memory usage of this solver has a quadratic dependency on `n_features` because it explicitly computes the Hessian matrix. .. versionadded:: 1.2 max_iter : int, default=100 The maximal number of iterations for the solver. Values must be in the range `[1, inf)`. tol : float, default=1e-4 Stopping criterion. For the lbfgs solver, the iteration will stop when ``max{|g_j|, j = 1, ..., d} <= tol`` where ``g_j`` is the j-th component of the gradient (derivative) of the objective function. Values must be in the range `(0.0, inf)`. warm_start : bool, default=False If set to ``True``, reuse the solution of the previous call to ``fit`` as initialization for `coef_` and `intercept_`. verbose : int, default=0 For the lbfgs solver set verbose to any positive number for verbosity. Values must be in the range `[0, inf)`. Attributes ---------- coef_ : array of shape (n_features,) Estimated coefficients for the linear predictor (`X @ coef_ + intercept_`) in the GLM. intercept_ : float Intercept (a.k.a. bias) added to linear predictor. n_features_in_ : int Number of features seen during :term:`fit`. .. versionadded:: 0.24 n_iter_ : int Actual number of iterations used in the solver. feature_names_in_ : ndarray of shape (`n_features_in_`,) Names of features seen during :term:`fit`. Defined only when `X` has feature names that are all strings. .. versionadded:: 1.0 See Also -------- PoissonRegressor : Generalized Linear Model with a Poisson distribution. TweedieRegressor : Generalized Linear Model with a Tweedie distribution. Examples -------- >>> from sklearn import linear_model >>> clf = linear_model.GammaRegressor() >>> X = [[1, 2], [2, 3], [3, 4], [4, 3]] >>> y = [19, 26, 33, 30] >>> clf.fit(X, y) GammaRegressor() >>> clf.score(X, y) 0.773... >>> clf.coef_ array([0.072..., 0.066...]) >>> clf.intercept_ 2.896... >>> clf.predict([[1, 0], [2, 8]]) array([19.483..., 35.795...]) """ _parameter_constraints: dict = { **_GeneralizedLinearRegressor._parameter_constraints } def __init__( self, *, alpha=1.0, fit_intercept=True, solver="lbfgs", max_iter=100, tol=1e-4, warm_start=False, verbose=0, ): super().__init__( alpha=alpha, fit_intercept=fit_intercept, solver=solver, max_iter=max_iter, tol=tol, warm_start=warm_start, verbose=verbose, ) def _get_loss(self): return HalfGammaLoss() class TweedieRegressor(_GeneralizedLinearRegressor): """Generalized Linear Model with a Tweedie distribution. This estimator can be used to model different GLMs depending on the ``power`` parameter, which determines the underlying distribution. Read more in the :ref:`User Guide `. .. versionadded:: 0.23 Parameters ---------- power : float, default=0 The power determines the underlying target distribution according to the following table: +-------+------------------------+ | Power | Distribution | +=======+========================+ | 0 | Normal | +-------+------------------------+ | 1 | Poisson | +-------+------------------------+ | (1,2) | Compound Poisson Gamma | +-------+------------------------+ | 2 | Gamma | +-------+------------------------+ | 3 | Inverse Gaussian | +-------+------------------------+ For ``0 < power < 1``, no distribution exists. alpha : float, default=1 Constant that multiplies the L2 penalty term and determines the regularization strength. ``alpha = 0`` is equivalent to unpenalized GLMs. In this case, the design matrix `X` must have full column rank (no collinearities). Values of `alpha` must be in the range `[0.0, inf)`. fit_intercept : bool, default=True Specifies if a constant (a.k.a. bias or intercept) should be added to the linear predictor (`X @ coef + intercept`). link : {'auto', 'identity', 'log'}, default='auto' The link function of the GLM, i.e. mapping from linear predictor `X @ coeff + intercept` to prediction `y_pred`. Option 'auto' sets the link depending on the chosen `power` parameter as follows: - 'identity' for ``power <= 0``, e.g. for the Normal distribution - 'log' for ``power > 0``, e.g. for Poisson, Gamma and Inverse Gaussian distributions solver : {'lbfgs', 'newton-cholesky'}, default='lbfgs' Algorithm to use in the optimization problem: 'lbfgs' Calls scipy's L-BFGS-B optimizer. 'newton-cholesky' Uses Newton-Raphson steps (in arbitrary precision arithmetic equivalent to iterated reweighted least squares) with an inner Cholesky based solver. This solver is a good choice for `n_samples` >> `n_features`, especially with one-hot encoded categorical features with rare categories. Be aware that the memory usage of this solver has a quadratic dependency on `n_features` because it explicitly computes the Hessian matrix. .. versionadded:: 1.2 max_iter : int, default=100 The maximal number of iterations for the solver. Values must be in the range `[1, inf)`. tol : float, default=1e-4 Stopping criterion. For the lbfgs solver, the iteration will stop when ``max{|g_j|, j = 1, ..., d} <= tol`` where ``g_j`` is the j-th component of the gradient (derivative) of the objective function. Values must be in the range `(0.0, inf)`. warm_start : bool, default=False If set to ``True``, reuse the solution of the previous call to ``fit`` as initialization for ``coef_`` and ``intercept_`` . verbose : int, default=0 For the lbfgs solver set verbose to any positive number for verbosity. Values must be in the range `[0, inf)`. Attributes ---------- coef_ : array of shape (n_features,) Estimated coefficients for the linear predictor (`X @ coef_ + intercept_`) in the GLM. intercept_ : float Intercept (a.k.a. bias) added to linear predictor. n_iter_ : int Actual number of iterations used in the solver. n_features_in_ : int Number of features seen during :term:`fit`. .. versionadded:: 0.24 feature_names_in_ : ndarray of shape (`n_features_in_`,) Names of features seen during :term:`fit`. Defined only when `X` has feature names that are all strings. .. versionadded:: 1.0 See Also -------- PoissonRegressor : Generalized Linear Model with a Poisson distribution. GammaRegressor : Generalized Linear Model with a Gamma distribution. Examples -------- >>> from sklearn import linear_model >>> clf = linear_model.TweedieRegressor() >>> X = [[1, 2], [2, 3], [3, 4], [4, 3]] >>> y = [2, 3.5, 5, 5.5] >>> clf.fit(X, y) TweedieRegressor() >>> clf.score(X, y) 0.839... >>> clf.coef_ array([0.599..., 0.299...]) >>> clf.intercept_ 1.600... >>> clf.predict([[1, 1], [3, 4]]) array([2.500..., 4.599...]) """ _parameter_constraints: dict = { **_GeneralizedLinearRegressor._parameter_constraints, "power": [Interval(Real, None, None, closed="neither")], "link": [StrOptions({"auto", "identity", "log"})], } def __init__( self, *, power=0.0, alpha=1.0, fit_intercept=True, link="auto", solver="lbfgs", max_iter=100, tol=1e-4, warm_start=False, verbose=0, ): super().__init__( alpha=alpha, fit_intercept=fit_intercept, solver=solver, max_iter=max_iter, tol=tol, warm_start=warm_start, verbose=verbose, ) self.link = link self.power = power def _get_loss(self): if self.link == "auto": if self.power <= 0: # identity link return HalfTweedieLossIdentity(power=self.power) else: # log link return HalfTweedieLoss(power=self.power) if self.link == "log": return HalfTweedieLoss(power=self.power) if self.link == "identity": return HalfTweedieLossIdentity(power=self.power)