Files
2026-07-13 13:39:55 +08:00

207 lines
6.3 KiB
Python

# coding:utf-8
import random
import numpy as np
from scipy import stats
from mla.ensemble.base import split, split_dataset, xgb_criterion
random.seed(111)
class Tree(object):
"""Recursive implementation of decision tree."""
def __init__(self, regression=False, criterion=None, n_classes=None):
self.regression = regression
self.impurity = None
self.threshold = None
self.column_index = None
self.outcome = None
self.criterion = criterion
self.loss = None
self.n_classes = n_classes # Only for classification
self.left_child = None
self.right_child = None
@property
def is_terminal(self):
return not bool(self.left_child and self.right_child)
def _find_splits(self, X):
"""Find all possible split values."""
split_values = set()
# Get unique values in a sorted order
x_unique = list(np.unique(X))
for i in range(1, len(x_unique)):
# Find a point between two values
average = (x_unique[i - 1] + x_unique[i]) / 2.0
split_values.add(average)
return list(split_values)
def _find_best_split(self, X, target, n_features):
"""Find best feature and value for a split. Greedy algorithm."""
# Sample random subset of features
subset = random.sample(list(range(0, X.shape[1])), n_features)
max_gain, max_col, max_val = None, None, None
for column in subset:
split_values = self._find_splits(X[:, column])
for value in split_values:
if self.loss is None:
# Random forest
splits = split(X[:, column], target["y"], value)
gain = self.criterion(target["y"], splits)
else:
# Gradient boosting
left, right = split_dataset(
X, target, column, value, return_X=False
)
gain = xgb_criterion(target, left, right, self.loss)
if (max_gain is None) or (gain > max_gain):
max_col, max_val, max_gain = column, value, gain
return max_col, max_val, max_gain
def _train(
self,
X,
target,
max_features=None,
min_samples_split=10,
max_depth=None,
minimum_gain=0.01,
):
try:
# Exit from recursion using assert syntax
assert X.shape[0] > min_samples_split
assert max_depth > 0
if max_features is None:
max_features = X.shape[1]
column, value, gain = self._find_best_split(X, target, max_features)
assert gain is not None
if self.regression:
assert gain != 0
else:
assert gain > minimum_gain
self.column_index = column
self.threshold = value
self.impurity = gain
# Split dataset
left_X, right_X, left_target, right_target = split_dataset(
X, target, column, value
)
# Grow left and right child
self.left_child = Tree(self.regression, self.criterion, self.n_classes)
self.left_child._train(
left_X,
left_target,
max_features,
min_samples_split,
max_depth - 1,
minimum_gain,
)
self.right_child = Tree(self.regression, self.criterion, self.n_classes)
self.right_child._train(
right_X,
right_target,
max_features,
min_samples_split,
max_depth - 1,
minimum_gain,
)
except AssertionError:
self._calculate_leaf_value(target)
def train(
self,
X,
target,
max_features=None,
min_samples_split=10,
max_depth=None,
minimum_gain=0.01,
loss=None,
):
"""Build a decision tree from training set.
Parameters
----------
X : array-like
Feature dataset.
target : dictionary or array-like
Target values.
max_features : int or None
The number of features to consider when looking for the best split.
min_samples_split : int
The minimum number of samples required to split an internal node.
max_depth : int
Maximum depth of the tree.
minimum_gain : float, default 0.01
Minimum gain required for splitting.
loss : function, default None
Loss function for gradient boosting.
"""
if not isinstance(target, dict):
target = {"y": target}
# Loss for gradient boosting
if loss is not None:
self.loss = loss
if not self.regression:
self.n_classes = len(np.unique(target["y"]))
self._train(
X,
target,
max_features=max_features,
min_samples_split=min_samples_split,
max_depth=max_depth,
minimum_gain=minimum_gain,
)
def _calculate_leaf_value(self, targets):
"""Find optimal value for leaf."""
if self.loss is not None:
# Gradient boosting
self.outcome = self.loss.approximate(targets["actual"], targets["y_pred"])
else:
# Random Forest
if self.regression:
# Mean value for regression task
self.outcome = np.mean(targets["y"])
else:
# Probability for classification task
self.outcome = (
np.bincount(targets["y"], minlength=self.n_classes)
/ targets["y"].shape[0]
)
def predict_row(self, row):
"""Predict single row."""
if not self.is_terminal:
if row[self.column_index] < self.threshold:
return self.left_child.predict_row(row)
else:
return self.right_child.predict_row(row)
return self.outcome
def predict(self, X):
result = np.zeros(X.shape[0])
for i in range(X.shape[0]):
result[i] = self.predict_row(X[i, :])
return result