153 lines
4.4 KiB
Python
153 lines
4.4 KiB
Python
# coding:utf-8
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import numpy as np
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# logistic function
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from scipy.special import expit
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from mla.base import BaseEstimator
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from mla.ensemble.base import mse_criterion
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from mla.ensemble.tree import Tree
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"""
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References:
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https://arxiv.org/pdf/1603.02754v3.pdf
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http://www.saedsayad.com/docs/xgboost.pdf
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https://homes.cs.washington.edu/~tqchen/pdf/BoostedTree.pdf
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http://stats.stackexchange.com/questions/202858/loss-function-approximation-with-taylor-expansion
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"""
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class Loss:
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"""Base class for loss functions."""
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def __init__(self, regularization=1.0):
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self.regularization = regularization
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def grad(self, actual, predicted):
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"""First order gradient."""
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raise NotImplementedError()
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def hess(self, actual, predicted):
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"""Second order gradient."""
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raise NotImplementedError()
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def approximate(self, actual, predicted):
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"""Approximate leaf value."""
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return self.grad(actual, predicted).sum() / (
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self.hess(actual, predicted).sum() + self.regularization
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)
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def transform(self, pred):
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"""Transform predictions values."""
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return pred
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def gain(self, actual, predicted):
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"""Calculate gain for split search."""
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nominator = self.grad(actual, predicted).sum() ** 2
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denominator = self.hess(actual, predicted).sum() + self.regularization
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return 0.5 * (nominator / denominator)
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class LeastSquaresLoss(Loss):
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"""Least squares loss"""
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def grad(self, actual, predicted):
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return actual - predicted
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def hess(self, actual, predicted):
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return np.ones_like(actual)
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class LogisticLoss(Loss):
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"""Logistic loss."""
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def grad(self, actual, predicted):
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return actual * expit(-actual * predicted)
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def hess(self, actual, predicted):
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expits = expit(predicted)
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return expits * (1 - expits)
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def transform(self, output):
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# Apply logistic (sigmoid) function to the output
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return expit(output)
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class GradientBoosting(BaseEstimator):
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"""Gradient boosting trees with Taylor's expansion approximation (as in xgboost)."""
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def __init__(
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self,
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n_estimators,
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learning_rate=0.1,
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max_features=10,
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max_depth=2,
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min_samples_split=10,
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):
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self.min_samples_split = min_samples_split
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self.learning_rate = learning_rate
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self.max_depth = max_depth
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self.max_features = max_features
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self.n_estimators = n_estimators
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self.trees = []
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self.loss = None
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def fit(self, X, y=None):
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self._setup_input(X, y)
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self.y_mean = np.mean(y)
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self._train()
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def _train(self):
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# Initialize model with zeros
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y_pred = np.zeros(self.n_samples, np.float32)
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# Or mean
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# y_pred = np.full(self.n_samples, self.y_mean)
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for n in range(self.n_estimators):
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residuals = self.loss.grad(self.y, y_pred)
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tree = Tree(regression=True, criterion=mse_criterion)
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# Pass multiple target values to the tree learner
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targets = {
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# Residual values
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"y": residuals,
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# Actual target values
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"actual": self.y,
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# Predictions from previous step
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"y_pred": y_pred,
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}
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tree.train(
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self.X,
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targets,
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max_features=self.max_features,
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min_samples_split=self.min_samples_split,
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max_depth=self.max_depth,
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loss=self.loss,
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)
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predictions = tree.predict(self.X)
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y_pred += self.learning_rate * predictions
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self.trees.append(tree)
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def _predict(self, X=None):
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y_pred = np.zeros(X.shape[0], np.float32)
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for i, tree in enumerate(self.trees):
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y_pred += self.learning_rate * tree.predict(X)
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return y_pred
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def predict(self, X=None):
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return self.loss.transform(self._predict(X))
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class GradientBoostingRegressor(GradientBoosting):
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def fit(self, X, y=None):
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self.loss = LeastSquaresLoss()
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super(GradientBoostingRegressor, self).fit(X, y)
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class GradientBoostingClassifier(GradientBoosting):
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def fit(self, X, y=None):
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# Convert labels from {0, 1} to {-1, 1}
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y = (y * 2) - 1
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self.loss = LogisticLoss()
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super(GradientBoostingClassifier, self).fit(X, y)
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