""" Generalized Linear Models. """ # Author: Alexandre Gramfort # Fabian Pedregosa # Olivier Grisel # Vincent Michel # Peter Prettenhofer # Mathieu Blondel # Lars Buitinck # Maryan Morel # Giorgio Patrini # License: BSD 3 clause from abc import ABCMeta, abstractmethod import numbers import warnings import numpy as np import scipy.sparse as sp from scipy import linalg from scipy import optimize from scipy import sparse from scipy.special import expit from joblib import Parallel from ..base import (BaseEstimator, ClassifierMixin, RegressorMixin, MultiOutputMixin) from ..utils import check_array from ..utils.validation import FLOAT_DTYPES from ..utils.validation import _deprecate_positional_args from ..utils import check_random_state from ..utils.extmath import safe_sparse_dot from ..utils.sparsefuncs import mean_variance_axis, inplace_column_scale from ..utils.fixes import sparse_lsqr from ..utils._seq_dataset import ArrayDataset32, CSRDataset32 from ..utils._seq_dataset import ArrayDataset64, CSRDataset64 from ..utils.validation import check_is_fitted, _check_sample_weight from ..utils.fixes import delayed from ..preprocessing import normalize as f_normalize # TODO: bayesian_ridge_regression and bayesian_regression_ard # should be squashed into its respective objects. SPARSE_INTERCEPT_DECAY = 0.01 # For sparse data intercept updates are scaled by this decay factor to avoid # intercept oscillation. def make_dataset(X, y, sample_weight, random_state=None): """Create ``Dataset`` abstraction for sparse and dense inputs. This also returns the ``intercept_decay`` which is different for sparse datasets. Parameters ---------- X : array-like, shape (n_samples, n_features) Training data y : array-like, shape (n_samples, ) Target values. sample_weight : numpy array of shape (n_samples,) The weight of each sample random_state : int, RandomState instance or None (default) Determines random number generation for dataset shuffling and noise. Pass an int for reproducible output across multiple function calls. See :term:`Glossary `. Returns ------- dataset The ``Dataset`` abstraction intercept_decay The intercept decay """ rng = check_random_state(random_state) # seed should never be 0 in SequentialDataset64 seed = rng.randint(1, np.iinfo(np.int32).max) if X.dtype == np.float32: CSRData = CSRDataset32 ArrayData = ArrayDataset32 else: CSRData = CSRDataset64 ArrayData = ArrayDataset64 if sp.issparse(X): dataset = CSRData(X.data, X.indptr, X.indices, y, sample_weight, seed=seed) intercept_decay = SPARSE_INTERCEPT_DECAY else: X = np.ascontiguousarray(X) dataset = ArrayData(X, y, sample_weight, seed=seed) intercept_decay = 1.0 return dataset, intercept_decay def _preprocess_data(X, y, fit_intercept, normalize=False, copy=True, sample_weight=None, return_mean=False, check_input=True): """Center and scale data. Centers data to have mean zero along axis 0. If fit_intercept=False or if the X is a sparse matrix, no centering is done, but normalization can still be applied. The function returns the statistics necessary to reconstruct the input data, which are X_offset, y_offset, X_scale, such that the output X = (X - X_offset) / X_scale X_scale is the L2 norm of X - X_offset. If sample_weight is not None, then the weighted mean of X and y is zero, and not the mean itself. If return_mean=True, the mean, eventually weighted, is returned, independently of whether X was centered (option used for optimization with sparse data in coordinate_descend). This is here because nearly all linear models will want their data to be centered. This function also systematically makes y consistent with X.dtype """ if isinstance(sample_weight, numbers.Number): sample_weight = None if sample_weight is not None: sample_weight = np.asarray(sample_weight) if check_input: X = check_array(X, copy=copy, accept_sparse=['csr', 'csc'], dtype=FLOAT_DTYPES) elif copy: if sp.issparse(X): X = X.copy() else: X = X.copy(order='K') y = np.asarray(y, dtype=X.dtype) if fit_intercept: if sp.issparse(X): X_offset, X_var = mean_variance_axis(X, axis=0) if not return_mean: X_offset[:] = X.dtype.type(0) if normalize: # TODO: f_normalize could be used here as well but the function # inplace_csr_row_normalize_l2 must be changed such that it # can return also the norms computed internally # transform variance to norm in-place X_var *= X.shape[0] X_scale = np.sqrt(X_var, X_var) del X_var X_scale[X_scale == 0] = 1 inplace_column_scale(X, 1. / X_scale) else: X_scale = np.ones(X.shape[1], dtype=X.dtype) else: X_offset = np.average(X, axis=0, weights=sample_weight) X -= X_offset if normalize: X, X_scale = f_normalize(X, axis=0, copy=False, return_norm=True) else: X_scale = np.ones(X.shape[1], dtype=X.dtype) y_offset = np.average(y, axis=0, weights=sample_weight) y = y - y_offset else: X_offset = np.zeros(X.shape[1], dtype=X.dtype) X_scale = np.ones(X.shape[1], dtype=X.dtype) if y.ndim == 1: y_offset = X.dtype.type(0) else: y_offset = np.zeros(y.shape[1], dtype=X.dtype) return X, y, X_offset, y_offset, X_scale # TODO: _rescale_data should be factored into _preprocess_data. # Currently, the fact that sag implements its own way to deal with # sample_weight makes the refactoring tricky. def _rescale_data(X, y, sample_weight): """Rescale data sample-wise by square root of sample_weight. For many linear models, this enables easy support for sample_weight. Returns ------- X_rescaled : {array-like, sparse matrix} y_rescaled : {array-like, sparse matrix} """ n_samples = X.shape[0] sample_weight = np.asarray(sample_weight) if sample_weight.ndim == 0: sample_weight = np.full(n_samples, sample_weight, dtype=sample_weight.dtype) sample_weight = np.sqrt(sample_weight) sw_matrix = sparse.dia_matrix((sample_weight, 0), shape=(n_samples, n_samples)) X = safe_sparse_dot(sw_matrix, X) y = safe_sparse_dot(sw_matrix, y) return X, y class LinearModel(BaseEstimator, metaclass=ABCMeta): """Base class for Linear Models""" @abstractmethod def fit(self, X, y): """Fit model.""" def _decision_function(self, X): check_is_fitted(self) X = check_array(X, accept_sparse=['csr', 'csc', 'coo']) return safe_sparse_dot(X, self.coef_.T, dense_output=True) + self.intercept_ def predict(self, X): """ Predict using the linear model. Parameters ---------- X : array-like or sparse matrix, shape (n_samples, n_features) Samples. Returns ------- C : array, shape (n_samples,) Returns predicted values. """ return self._decision_function(X) _preprocess_data = staticmethod(_preprocess_data) def _set_intercept(self, X_offset, y_offset, X_scale): """Set the intercept_ """ if self.fit_intercept: self.coef_ = self.coef_ / X_scale self.intercept_ = y_offset - np.dot(X_offset, self.coef_.T) else: self.intercept_ = 0. def _more_tags(self): return {'requires_y': True} # XXX Should this derive from LinearModel? It should be a mixin, not an ABC. # Maybe the n_features checking can be moved to LinearModel. class LinearClassifierMixin(ClassifierMixin): """Mixin for linear classifiers. Handles prediction for sparse and dense X. """ def decision_function(self, X): """ Predict confidence scores for samples. The confidence score for a sample is proportional to the signed distance of that sample to the hyperplane. Parameters ---------- X : array-like or sparse matrix, shape (n_samples, n_features) Samples. Returns ------- array, shape=(n_samples,) if n_classes == 2 else (n_samples, n_classes) Confidence scores per (sample, class) combination. In the binary case, confidence score for self.classes_[1] where >0 means this class would be predicted. """ check_is_fitted(self) X = check_array(X, accept_sparse='csr') n_features = self.coef_.shape[1] if X.shape[1] != n_features: raise ValueError("X has %d features per sample; expecting %d" % (X.shape[1], n_features)) scores = safe_sparse_dot(X, self.coef_.T, dense_output=True) + self.intercept_ return scores.ravel() if scores.shape[1] == 1 else scores def predict(self, X): """ Predict class labels for samples in X. Parameters ---------- X : array-like or sparse matrix, shape (n_samples, n_features) Samples. Returns ------- C : array, shape [n_samples] Predicted class label per sample. """ scores = self.decision_function(X) if len(scores.shape) == 1: indices = (scores > 0).astype(int) else: indices = scores.argmax(axis=1) return self.classes_[indices] def _predict_proba_lr(self, X): """Probability estimation for OvR logistic regression. Positive class probabilities are computed as 1. / (1. + np.exp(-self.decision_function(X))); multiclass is handled by normalizing that over all classes. """ prob = self.decision_function(X) expit(prob, out=prob) if prob.ndim == 1: return np.vstack([1 - prob, prob]).T else: # OvR normalization, like LibLinear's predict_probability prob /= prob.sum(axis=1).reshape((prob.shape[0], -1)) return prob class SparseCoefMixin: """Mixin for converting coef_ to and from CSR format. L1-regularizing estimators should inherit this. """ def densify(self): """ Convert coefficient matrix to dense array format. Converts the ``coef_`` member (back) to a numpy.ndarray. This is the default format of ``coef_`` and is required for fitting, so calling this method is only required on models that have previously been sparsified; otherwise, it is a no-op. Returns ------- self Fitted estimator. """ msg = "Estimator, %(name)s, must be fitted before densifying." check_is_fitted(self, msg=msg) if sp.issparse(self.coef_): self.coef_ = self.coef_.toarray() return self def sparsify(self): """ Convert coefficient matrix to sparse format. Converts the ``coef_`` member to a scipy.sparse matrix, which for L1-regularized models can be much more memory- and storage-efficient than the usual numpy.ndarray representation. The ``intercept_`` member is not converted. Returns ------- self Fitted estimator. Notes ----- For non-sparse models, i.e. when there are not many zeros in ``coef_``, this may actually *increase* memory usage, so use this method with care. A rule of thumb is that the number of zero elements, which can be computed with ``(coef_ == 0).sum()``, must be more than 50% for this to provide significant benefits. After calling this method, further fitting with the partial_fit method (if any) will not work until you call densify. """ msg = "Estimator, %(name)s, must be fitted before sparsifying." check_is_fitted(self, msg=msg) self.coef_ = sp.csr_matrix(self.coef_) return self class LinearRegression(MultiOutputMixin, RegressorMixin, LinearModel): """ Ordinary least squares Linear Regression. LinearRegression fits a linear model with coefficients w = (w1, ..., wp) to minimize the residual sum of squares between the observed targets in the dataset, and the targets predicted by the linear approximation. Parameters ---------- fit_intercept : bool, default=True Whether to calculate the intercept for this model. If set to False, no intercept will be used in calculations (i.e. data is expected to be centered). normalize : bool, default=False This parameter is ignored when ``fit_intercept`` is set to False. If True, the regressors X will be normalized before regression by subtracting the mean and dividing by the l2-norm. If you wish to standardize, please use :class:`~sklearn.preprocessing.StandardScaler` before calling ``fit`` on an estimator with ``normalize=False``. copy_X : bool, default=True If True, X will be copied; else, it may be overwritten. n_jobs : int, default=None The number of jobs to use for the computation. This will only provide speedup for n_targets > 1 and sufficient large problems. ``None`` means 1 unless in a :obj:`joblib.parallel_backend` context. ``-1`` means using all processors. See :term:`Glossary ` for more details. positive : bool, default=False When set to ``True``, forces the coefficients to be positive. This option is only supported for dense arrays. .. versionadded:: 0.24 Attributes ---------- coef_ : array of shape (n_features, ) or (n_targets, n_features) Estimated coefficients for the linear regression problem. If multiple targets are passed during the fit (y 2D), this is a 2D array of shape (n_targets, n_features), while if only one target is passed, this is a 1D array of length n_features. rank_ : int Rank of matrix `X`. Only available when `X` is dense. singular_ : array of shape (min(X, y),) Singular values of `X`. Only available when `X` is dense. intercept_ : float or array of shape (n_targets,) Independent term in the linear model. Set to 0.0 if `fit_intercept = False`. See Also -------- Ridge : Ridge regression addresses some of the problems of Ordinary Least Squares by imposing a penalty on the size of the coefficients with l2 regularization. Lasso : The Lasso is a linear model that estimates sparse coefficients with l1 regularization. ElasticNet : Elastic-Net is a linear regression model trained with both l1 and l2 -norm regularization of the coefficients. Notes ----- From the implementation point of view, this is just plain Ordinary Least Squares (scipy.linalg.lstsq) or Non Negative Least Squares (scipy.optimize.nnls) wrapped as a predictor object. Examples -------- >>> import numpy as np >>> from sklearn.linear_model import LinearRegression >>> X = np.array([[1, 1], [1, 2], [2, 2], [2, 3]]) >>> # y = 1 * x_0 + 2 * x_1 + 3 >>> y = np.dot(X, np.array([1, 2])) + 3 >>> reg = LinearRegression().fit(X, y) >>> reg.score(X, y) 1.0 >>> reg.coef_ array([1., 2.]) >>> reg.intercept_ 3.0... >>> reg.predict(np.array([[3, 5]])) array([16.]) """ @_deprecate_positional_args def __init__(self, *, fit_intercept=True, normalize=False, copy_X=True, n_jobs=None, positive=False): self.fit_intercept = fit_intercept self.normalize = normalize self.copy_X = copy_X self.n_jobs = n_jobs self.positive = positive def fit(self, X, y, sample_weight=None): """ Fit linear model. Parameters ---------- X : {array-like, sparse matrix} of shape (n_samples, n_features) Training data y : array-like of shape (n_samples,) or (n_samples, n_targets) Target values. Will be cast to X's dtype if necessary sample_weight : array-like of shape (n_samples,), default=None Individual weights for each sample .. versionadded:: 0.17 parameter *sample_weight* support to LinearRegression. Returns ------- self : returns an instance of self. """ n_jobs_ = self.n_jobs accept_sparse = False if self.positive else ['csr', 'csc', 'coo'] X, y = self._validate_data(X, y, accept_sparse=accept_sparse, y_numeric=True, multi_output=True) if sample_weight is not None: sample_weight = _check_sample_weight(sample_weight, X, dtype=X.dtype) X, y, X_offset, y_offset, X_scale = self._preprocess_data( X, y, fit_intercept=self.fit_intercept, normalize=self.normalize, copy=self.copy_X, sample_weight=sample_weight, return_mean=True) if sample_weight is not None: # Sample weight can be implemented via a simple rescaling. X, y = _rescale_data(X, y, sample_weight) if self.positive: if y.ndim < 2: self.coef_, self._residues = optimize.nnls(X, y) else: # scipy.optimize.nnls cannot handle y with shape (M, K) outs = Parallel(n_jobs=n_jobs_)( delayed(optimize.nnls)(X, y[:, j]) for j in range(y.shape[1])) self.coef_, self._residues = map(np.vstack, zip(*outs)) elif sp.issparse(X): X_offset_scale = X_offset / X_scale def matvec(b): return X.dot(b) - b.dot(X_offset_scale) def rmatvec(b): return X.T.dot(b) - X_offset_scale * np.sum(b) X_centered = sparse.linalg.LinearOperator(shape=X.shape, matvec=matvec, rmatvec=rmatvec) if y.ndim < 2: out = sparse_lsqr(X_centered, y) self.coef_ = out[0] self._residues = out[3] else: # sparse_lstsq cannot handle y with shape (M, K) outs = Parallel(n_jobs=n_jobs_)( delayed(sparse_lsqr)(X_centered, y[:, j].ravel()) for j in range(y.shape[1])) self.coef_ = np.vstack([out[0] for out in outs]) self._residues = np.vstack([out[3] for out in outs]) else: self.coef_, self._residues, self.rank_, self.singular_ = \ linalg.lstsq(X, y) self.coef_ = self.coef_.T if y.ndim == 1: self.coef_ = np.ravel(self.coef_) self._set_intercept(X_offset, y_offset, X_scale) return self def _pre_fit(X, y, Xy, precompute, normalize, fit_intercept, copy, check_input=True, sample_weight=None): """Aux function used at beginning of fit in linear models Parameters ---------- order : 'F', 'C' or None, default=None Whether X and y will be forced to be fortran or c-style. Only relevant if sample_weight is not None. """ n_samples, n_features = X.shape if sparse.isspmatrix(X): # copy is not needed here as X is not modified inplace when X is sparse precompute = False X, y, X_offset, y_offset, X_scale = _preprocess_data( X, y, fit_intercept=fit_intercept, normalize=normalize, copy=False, return_mean=True, check_input=check_input) else: # copy was done in fit if necessary X, y, X_offset, y_offset, X_scale = _preprocess_data( X, y, fit_intercept=fit_intercept, normalize=normalize, copy=copy, check_input=check_input, sample_weight=sample_weight) if sample_weight is not None: X, y = _rescale_data(X, y, sample_weight=sample_weight) if hasattr(precompute, '__array__') and ( fit_intercept and not np.allclose(X_offset, np.zeros(n_features)) or normalize and not np.allclose(X_scale, np.ones(n_features))): warnings.warn("Gram matrix was provided but X was centered" " to fit intercept, " "or X was normalized : recomputing Gram matrix.", UserWarning) # recompute Gram precompute = 'auto' Xy = None # precompute if n_samples > n_features if isinstance(precompute, str) and precompute == 'auto': precompute = (n_samples > n_features) if precompute is True: # make sure that the 'precompute' array is contiguous. precompute = np.empty(shape=(n_features, n_features), dtype=X.dtype, order='C') np.dot(X.T, X, out=precompute) if not hasattr(precompute, '__array__'): Xy = None # cannot use Xy if precompute is not Gram if hasattr(precompute, '__array__') and Xy is None: common_dtype = np.find_common_type([X.dtype, y.dtype], []) if y.ndim == 1: # Xy is 1d, make sure it is contiguous. Xy = np.empty(shape=n_features, dtype=common_dtype, order='C') np.dot(X.T, y, out=Xy) else: # Make sure that Xy is always F contiguous even if X or y are not # contiguous: the goal is to make it fast to extract the data for a # specific target. n_targets = y.shape[1] Xy = np.empty(shape=(n_features, n_targets), dtype=common_dtype, order='F') np.dot(y.T, X, out=Xy.T) return X, y, X_offset, y_offset, X_scale, precompute, Xy