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Jamie Hall 2015-04-01 23:29:05 -07:00
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demo/guide-python/sklearn_examples.py Normal file
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'''
Created on 1 Apr 2015
@author: Jamie Hall
'''
import sys
sys.path.append('../../wrapper')
import xgboost as xgb
import numpy as np
from sklearn.cross_validation import KFold
from sklearn.grid_search import GridSearchCV
from sklearn.metrics import confusion_matrix
from sklearn.datasets import load_iris, load_digits, load_boston
rng = np.random.RandomState(31337)
print("Zeros and Ones from the Digits dataset: binary classification")
digits = load_digits(2)
y = digits['target']
X = digits['data']
kf = KFold(y.shape[0], n_folds=2, shuffle=True, random_state=rng)
for train_index, test_index in kf:
xgb_model = xgb.XGBClassifier().fit(X[train_index],y[train_index])
predictions = xgb_model.predict(X[test_index])
actuals = y[test_index]
print(confusion_matrix(actuals, predictions))
print("Iris: multiclass classification")
iris = load_iris()
y = iris['target']
X = iris['data']
kf = KFold(y.shape[0], n_folds=2, shuffle=True, random_state=rng)
for train_index, test_index in kf:
xgb_model = xgb.XGBClassifier().fit(X[train_index],y[train_index])
predictions = xgb_model.predict(X[test_index])
actuals = y[test_index]
print(confusion_matrix(actuals, predictions))

127
wrapper/xgboost.py
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@ -14,6 +14,15 @@ import collections
import numpy as np import numpy as np
import scipy.sparse import scipy.sparse
try:
from sklearn.base import BaseEstimator
from sklearn.preprocessing import LabelEncoder
SKLEARN_INSTALLED = True
except ImportError:
SKLEARN_INSTALLED = False
__all__ = ['DMatrix', 'CVPack', 'Booster', 'aggcv', 'cv', 'mknfold', 'train'] __all__ = ['DMatrix', 'CVPack', 'Booster', 'aggcv', 'cv', 'mknfold', 'train']
if sys.version_info[0] == 3: if sys.version_info[0] == 3:
@ -660,3 +669,121 @@ def cv(params, dtrain, num_boost_round=10, nfold=3, metrics=(),
sys.stderr.write(res + '\n') sys.stderr.write(res + '\n')
results.append(res) results.append(res)
return results return results
XGBModelBase = object
if SKLEARN_INSTALLED:
XGBModelBase = BaseEstimator
class XGBModel(BaseEstimator):
"""
Implementation of the Scikit-Learn API for XGBoost.
Parameters
----------
max_depth : int
Maximum tree depth for base learners.
learning_rate : float
Boosting learning rate (xgb's "eta")
n_estimators : int
Number of boosted trees to fit.
silent : boolean
Whether to print messages while running boosting.
"""
def __init__(self, max_depth=3, learning_rate=0.1, n_estimators=100, silent=True, objective="reg:linear"):
if not SKLEARN_INSTALLED:
raise Exception('sklearn needs to be installed in order to use this module')
self.max_depth = max_depth
self.eta = learning_rate
self.silent = 1 if silent else 0
self.n_rounds = n_estimators
self.objective = objective
self._Booster = Booster()
def get_params(self, deep=True):
return {'max_depth': self.max_depth,
'learning_rate': self.eta,
'n_estimators': self.n_rounds,
'silent': True if self.silent == 1 else False,
'objective': self.objective
}
def get_xgb_params(self):
return {'eta': self.eta, 'max_depth': self.max_depth, 'silent': self.silent, 'objective': self.objective}
def fit(self, X, y):
trainDmatrix = DMatrix(X, label=y)
self._Booster = train(self.get_xgb_params(), trainDmatrix, self.n_rounds)
return self
class XGBClassifier(XGBModel):
def __init__(self, max_depth=3, learning_rate=0.1, n_estimators=100, silent=True):
super().__init__(max_depth, learning_rate, n_estimators, silent, objective="binary:logistic")
def fit(self, X, y, sample_weight=None):
y_values = list(np.unique(y))
if len(y_values) == 2:
# Map the two classes in the y vector into {0,1}, and record the mapping so that
# the predict() method can return results in the original range
if not (-1 in y_values and 1 in y_values) or (0 in y_values and 1 in y_values) or (True in y_values and False in y_values):
raise ValueError("For a binary classifier, y must be in (0,1), or (-1,1), or (True,False).")
if -1 in y_values:
self._yspace = "svm_like"
training_labels = y.copy()
training_labels[training_labels == -1] = 0
elif False in y_values:
self._yspace = "boolean"
training_labels = np.array(y, dtype=int)
else:
self._yspace = "zero_one"
training_labels = y
xgb_options = self.get_xgb_params()
else:
# Switch to using a multiclass objective in the underlying XGB instance
self._yspace = "multiclass"
self.objective = "multi:softprob"
self._le = LabelEncoder().fit(y)
training_labels = self._le.transform(y)
xgb_options = self.get_xgb_params()
xgb_options['num_class'] = len(y_values)
if sample_weight is not None:
trainDmatrix = DMatrix(X, label=training_labels, weight=sample_weight)
else:
trainDmatrix = DMatrix(X, label=training_labels)
self._Booster = train(xgb_options, trainDmatrix, self.n_rounds)
return self
def predict(self, X):
testDmatrix = DMatrix(X)
class_probs = self._Booster.predict(testDmatrix)
if self._yspace == "multiclass":
column_indexes = np.argmax(class_probs, axis=1)
fitted_values = self._le.inverse_transform(column_indexes)
else:
if self._yspace == "svm_like":
base_value = -1
one_value = 1
elif self._yspace == "boolean":
base_value = False
one_value = True
else:
base_value = 0
one_value = 1
fitted_values = np.repeat(base_value, X.shape[0])
fitted_values[class_probs > 0.5] = one_value
return fitted_values
def predict_proba(self, X):
testDmatrix = DMatrix(X)
class_probs = self._Booster.predict(testDmatrix)
if self._yspace == "multiclass":
return class_probs
else:
classone_probs = class_probs
classzero_probs = 1.0 - classone_probs
return np.vstack((classzero_probs,classone_probs)).transpose()