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model_fairxgb.py
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model_fairxgb.py
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"""Fair XGB """
import uuid
import os
import datatable as dt
import numpy as np
from h2oaicore.models import CustomModel
from sklearn.preprocessing import LabelEncoder
from h2oaicore.systemutils import user_dir, max_threads
from h2oaicore.systemutils import make_experiment_logger, loggerdata, loggerwarning, loggerdebug, loggerinfo
class FAIRXGBOOST(CustomModel):
_regression = False
_binary = True
_multiclass = False
_display_name = "Fair_XGBOOST"
_description = "Fair_XGBOOST"
@staticmethod
def do_acceptance_test():
return True
def set_default_params(self, accuracy=None, time_tolerance=None,
interpretability=None, **kwargs):
self.params = dict(random_state=kwargs.get("random_state", 24),
eta=0.1, max_depth=12, min_child_weight=2.0,
reg_lambda=1.0, colsample_bytree=0.8,
subsample=1.0, mu=0.1, reg_alpha=0,
)
def mutate_params(self, accuracy=10, **kwargs):
if accuracy > 8:
eta = [0.5, 0.1, 0.05, 0.01]
max_depth = list(range(4, 21))
min_child_weight = [0.1, 0.5, 1.0, 2.0, 4.0, 8.0, 16.0, 32.0]
reg_lambda = [0.0, 0.1, 1.0, 2.0, 5.0, 8.0, 10.0, 20.0]
reg_alpha = [0.0, 0.1, 1.0, 5.0, 10.0]
colsample_bytree = [0.1 * ii for ii in range(1, 11)]
subsample = [0.5, 0.8, 0.9, 1.0]
mu = [0.05 * ii for ii in range(1, 14)]
elif accuracy >= 5:
eta = [0.5, 0.1, 0.05]
max_depth = list(range(4, 21, 2))
min_child_weight = [0.1, 0.5, 1.0, 2.0, 4.0, 8.0, 16.0, 32.0]
reg_lambda = [0.0, 0.1, 1.0, 2.0, 5.0, 8.0, 10.0, 20.0]
reg_alpha = [0.0, 0.1, 1.0]
colsample_bytree = [0.1 * ii for ii in range(2, 11, 2)]
subsample = [1.0]
mu = [0.05 * ii for ii in range(1, 14)]
else:
eta = [0.1]
max_depth = list(range(4, 21, 2))
min_child_weight = [0.1, 0.5, 1.0, 2.0, 4.0, 8.0, 16.0, 32.0]
reg_lambda = [0.0, 0.1, 1.0, 5.0, 10.0]
reg_alpha = [0.0]
colsample_bytree = [0.1 * ii for ii in range(2, 11, 2)]
subsample = [1.0]
mu = [0.05 * ii for ii in range(1, 14)]
self.params["eta"] = np.random.choice(eta)
self.params["max_depth"] = np.random.choice(max_depth)
self.params["min_child_weight"] = np.random.choice(min_child_weight)
self.params["reg_lambda"] = np.random.choice(reg_lambda)
self.params["reg_alpha"] = np.random.choice(reg_alpha)
self.params["colsample_bytree"] = np.random.choice(colsample_bytree)
self.params["subsample"] = np.random.choice(subsample)
self.params["mu"] = np.random.choice(mu)
def _create_tmp_folder(self, logger):
# Create a temp folder to store files
# Set the default value without context available (required to pass acceptance test)
tmp_folder = os.path.join(user_dir(), "%s_FAIRXGB_model_folder" % uuid.uuid4())
# Make a real tmp folder when experiment is available
if self.context and self.context.experiment_id:
tmp_folder = os.path.join(self.context.experiment_tmp_dir, "%s_FAIRXGB_model_folder" % uuid.uuid4())
# Now let's try to create that folder
try:
os.mkdir(tmp_folder)
except PermissionError:
# This not occur so log a warning
loggerwarning(logger, "FAIRXGB was denied temp folder creation rights")
tmp_folder = os.path.join(user_dir(), "%s_FAIRXGB_model_folder" % uuid.uuid4())
os.mkdir(tmp_folder)
except FileExistsError:
# We should never be here since temp dir name is expected to be unique
loggerwarning(logger, "FAIRXGB temp folder already exists")
tmp_folder = os.path.join(self.context.experiment_tmp_dir, "%s_FAIRXGB_model_folder" % uuid.uuid4())
os.mkdir(tmp_folder)
except:
# Revert to temporary file path
tmp_folder = os.path.join(user_dir(), "%s_FAIRXGB_model_folder" % uuid.uuid4())
os.mkdir(tmp_folder)
loggerdata(logger, "FAIRXGB temp folder {}".format(tmp_folder))
return tmp_folder
def fit(self, X, y, sample_weight=None, eval_set=None, sample_weight_eval_set=None, **kwargs):
# Specify these parameters for the dataset.
#
# Also set feature engineering effort to 0
# under the features section of expert settings.
########################
# Specify the protected column.
# The protected column must be numeric.
self.protected_name = "black"
# Specify the level of the protected group in the protected column
self.protected_label = 1
# Specify the target level considered to be a positive outcome
# Must be encoded as 0/1
self.positive_target = 0
# Set minimum mean protected ratio needed to avoid a penalty
# (mean protected ratio = mean predictions for the protected group/mean predictions for all other groups)
#
# Try tuning this to values at or a little above
# the mean of the positive target for the protected group
# divided by the mean of the positive target for the unprotected group.
# If it's set too large, the accuracy will be poor, so there
# is a limit to the debiasing that can be obtained.
self.mean_protected_prediction_ratio_minimum = 0.92
########################
orig_cols = list(X.names)
import pandas as pd
import numpy as np
from sklearn.preprocessing import OneHotEncoder
from collections import Counter
import xgboost as xgb
# Get the logger if it exists
logger = None
if self.context and self.context.experiment_id:
logger = make_experiment_logger(experiment_id=self.context.experiment_id,
tmp_dir=self.context.tmp_dir,
experiment_tmp_dir=self.context.experiment_tmp_dir)
# Current mu value
mu = self.params["mu"]
def fair_metric(predt: np.ndarray, dtrain: xgb.DMatrix):
''' FairXGB Error Metric'''
# predt is the prediction array
# Find the right protected group vector
if len(predt) == len(protected_train):
protected_feature = np.array(protected_train.copy())
elif len(predt) == len(protected_full):
protected_feature = np.array(protected_full.copy())
elif len(predt) == len(protected_valid):
protected_feature = np.array(protected_valid.copy())
else:
protected_feature = 0
y = dtrain.get_label()
answer = - y * np.log(sigmoid(predt)) - (1 - y) * np.log(1 - sigmoid(predt))
answer += mu * (protected_feature * np.log(sigmoid(predt)) + (1 - protected_feature) * np.log(
1 - sigmoid(predt)))
return 'Fair_Metric', float(np.sum(answer) / len(answer))
def sigmoid(x):
z = 1.0 / (1.0 + np.exp(-x))
return z
def gradient(predt: np.ndarray, dtrain: xgb.DMatrix):
'''Fair Xgboost Gradient'''
# predt is the prediction array
# Find the right protected group vector
if len(predt) == len(protected_train):
protected_feature = np.array(protected_train.copy())
elif len(predt) == len(protected_full):
protected_feature = np.array(protected_full.copy())
elif len(predt) == len(protected_valid):
protected_feature = np.array(protected_valid.copy())
else:
protected_feature = 0
y = dtrain.get_label()
answer = sigmoid(predt) - y
answer += mu * (protected_feature - sigmoid(predt))
return answer
def hessian(predt: np.ndarray, dtrain: xgb.DMatrix):
'''Fair Xgboost Hessian'''
# predt is the prediction array
answer = (1 - mu) * sigmoid(predt) * (1 - sigmoid(predt))
return answer
def fair(predt: np.ndarray, dtrain: xgb.DMatrix):
''' Fair xgb objective function
'''
grad = gradient(predt, dtrain)
hess = hessian(predt, dtrain)
return grad, hess
# Set up model
params = {}
if self.num_classes >= 2:
lb = LabelEncoder()
lb.fit(self.labels)
y = lb.transform(y)
params['eta'] = self.params["eta"]
params['max_depth'] = self.params['max_depth']
params['min_child_weight'] = self.params['min_child_weight']
params['reg_lambda'] = self.params['reg_lambda']
params['reg_alpha'] = self.params['reg_alpha']
params['colsample_bytree'] = self.params['colsample_bytree']
params['subsample'] = self.params['subsample']
params['silent'] = 1
params['seed'] = self.params['random_state']
params['n_jobs'] = params['nthread'] = self.n_jobs
else:
# fairxgb doesn't work for regression
loggerinfo(logger, "PASS, no fairxgboost model")
pass
# Switch to pandas
X = X.to_pandas()
X.columns = orig_cols
# Find the protected group column if it is present
self.protected = "none"
for col in X.columns:
if col.find(self.protected_name) > -1:
self.protected = col
X_datatypes = [str(item) for item in list(X.dtypes)]
# List the categorical and numerical features
self.X_categorical = [orig_cols[col_count] for col_count in range(len(orig_cols)) if
(X_datatypes[col_count] == 'category') or (X_datatypes[col_count] == 'object')]
self.X_numeric = [item for item in orig_cols if item not in self.X_categorical]
self.encoded_categories = []
# Find the levels and mode for each categorical feature
# for use in the test set
self.train_levels = {}
for item in self.X_categorical:
self.train_levels[item] = list(set(X[item]))
self.train_mode[item] = Counter(X[item]).most_common(1)[0][0]
# One hot encode the categorical features
# And replace missing values with a Missing category
if len(self.X_categorical) > 0:
loggerinfo(logger, "Categorical encode")
for colname in self.X_categorical:
X[colname] = list(X[colname].fillna("Missing"))
self.enc = OneHotEncoder(handle_unknown='ignore')
if self.protected in self.X_categorical:
self.X_categorical.remove(self.protected)
if len(self.X_categorical) > 0:
self.enc.fit(X[self.X_categorical])
self.encoded_categories = list(self.enc.get_feature_names(input_features=self.X_categorical))
X_enc = self.enc.transform(X[self.X_categorical]).toarray()
X = pd.concat([X[self.X_numeric], pd.DataFrame(X_enc, columns=self.encoded_categories)], axis=1)
# Replace missing values with a missing value code
if len(self.X_numeric) > 0:
for colname in self.X_numeric:
X[colname] = list(X[colname].fillna(-999))
# Make sure the target that represents a positive outcome is 1
if self.positive_target == 0:
y = 1 - y
X_full = X.copy()
y_full = y.copy()
# Set up a validation step to find the optimal number of trees
X_valid = X.iloc[int(0.7 * len(X_full)):, :]
y_valid = y[int(0.7 * len(X_full)):]
X = X.iloc[0:int(0.7 * len(X_full)), :]
y = y[0:int(0.7 * len(X_full))]
if self.protected != "none":
# Set the protected group to 0 and all others 1
protected_full = [int(item) for item in ~(np.array(X_full[self.protected]) == self.protected_label)]
protected_train = [int(item) for item in ~(np.array(X[self.protected]) == self.protected_label)]
protected_valid = [int(item) for item in ~(np.array(X_valid[self.protected]) == self.protected_label)]
else:
mu = 0
protected_full = []
protected_train = []
protected_valid = []
# Remove the protected value from the model
if self.protected != "none":
X = X.drop(self.protected, axis=1)
X_full = X_full.drop(self.protected, axis=1)
X_valid = X_valid.drop(self.protected, axis=1)
d_train = xgb.DMatrix(X, label=y, missing=np.nan, nthread=self.n_jobs)
d_valid = xgb.DMatrix(X_valid, label=y_valid, missing=np.nan, nthread=self.n_jobs)
# Initial run to find the optimal number of trees
num_iterations = 10000
watchlist = [(d_train, 'train'), (d_valid, 'valid')]
clf = xgb.train(params, d_train, num_iterations, watchlist, feval=fair_metric, verbose_eval=10, obj=fair,
early_stopping_rounds=10)
# Second xgboost run with the full dataset and optimal number of trees
attribute_dict = clf.attributes()
new_iterations = int(attribute_dict['best_iteration'])
d_train = xgb.DMatrix(X_full, label=y_full, missing=np.nan, nthread=self.n_jobs)
watchlist = [(d_train, 'train')]
clf = xgb.train(params, d_train, new_iterations, watchlist, feval=fair_metric, verbose_eval=10, obj=fair)
# Calculate feature importances
importances_dict = clf.get_score(importance_type='gain')
# Make sure the protected group has high feature importance
# so that it doesn't get dropped by driverless
if self.protected != "none":
if len(importances_dict) > 0:
importances_dict[self.protected] = max(importances_dict.values())
else:
importances_dict[self.protected] = 1
for col in list(X.columns):
importances_dict[col] = 1
# Make sure any dropped columns are listed with 0 importance
for col in list(X.columns):
if col not in importances_dict:
importances_dict[col] = 0
self.mean_target = np.array(sum(y) / len(y))
loggerinfo(logger, "End fair check")
loggerinfo(logger, str(mu))
loggerdata(logger, str(importances_dict))
self.is_train = True
# Set model properties
self.set_model_properties(model=clf,
features=list(importances_dict.keys()),
importances=list(importances_dict.values()),
iterations=num_iterations)
def predict(self, X, **kwargs):
orig_cols = list(X.names)
import pandas as pd
import xgboost as xgb
import numpy as np
def sigmoid(x):
z = 1.0 / (1.0 + np.exp(-x))
return z
# Get the logger if it exists
logger = None
if self.context and self.context.experiment_id:
logger = make_experiment_logger(experiment_id=self.context.experiment_id,
tmp_dir=self.context.tmp_dir,
experiment_tmp_dir=self.context.experiment_tmp_dir)
X = dt.Frame(X)
X = X.to_pandas()
if self.protected in list(X.columns):
# Set the protected group to 0 and all others 1
loggerdebug(logger, "Protected test found")
protected_test = np.array([int(item) for item in ~(np.array(X[self.protected]) == self.protected_label)])
else:
loggerdebug(logger, "Protected test not found")
protected_test = np.array([])
if self.protected in list(X.columns):
X = X.drop(self.protected, axis=1)
# Replace missing values with a missing category
# Replace categories that weren't in the training set with the mode
if len(self.X_categorical) > 0:
for colname in self.X_categorical:
if colname in list(X.columns):
X[colname] = list(X[colname].fillna("Missing"))
for label in self.X_categorical:
if label in list(X.columns):
# Replace anything not in the test set
train_categories = self.train_levels[label]
X_label = np.array(X[label])
mmode = self.train_mode[label]
X_label[~np.isin(X_label, train_categories)] = mmode
X[label] = X_label
# Replace missing values with a missing value code
if len(self.X_numeric) > 0:
for colname in self.X_numeric:
if colname in list(X.columns):
X[colname] = list(X[colname].fillna(-999))
# Get model
model, _, _, _ = self.get_model_properties()
# Remove the protected group
if self.protected in self.X_categorical:
self.X_categorical.remove(self.protected)
# One hot encode categorical features
if len(self.X_categorical) > 0:
X_enc = self.enc.transform(X[self.X_categorical]).toarray()
X = pd.concat([X[self.X_numeric], pd.DataFrame(X_enc, columns=self.encoded_categories)], axis=1)
d_test = xgb.DMatrix(X, missing=np.nan, nthread=self.n_jobs)
# If the positive target was 0, change the final result to 1-p
if self.positive_target == 0:
preds = 1.0 - sigmoid(model.predict(d_test))
else:
preds = sigmoid(model.predict(d_test))
mean_preds = np.mean(preds)
# Set a penalty value to which some probabilities will be changed
# if the fairness threshold isn't reached
epsilon = 0.0001
if mean_preds > 0.5:
penalty = epsilon
else:
penalty = 1.0 - epsilon
# Only apply penalties in the training stage
if self.is_train:
# If the protected value was removed, use the maximum penalty
# by changing all probabilities to the penalty value
# (the recipe needs to be able to use the protected values)
if self.protected == "none":
preds[0:len(preds)] = penalty
loggerdata(logger, str(preds))
loggerdata(logger, "Removal_penalty")
else:
# The mean ratio calculation for target=0 and target=1
if self.positive_target == 0:
if np.mean(preds[protected_test == 1]) < 1.0:
DI = (1.0 - np.mean(preds[protected_test == 0])) / (1.0 - np.mean(preds[protected_test == 1]))
else:
DI = 1
else:
if np.mean(preds[protected_test == 1]) > 0.0:
DI = np.mean(preds[protected_test == 0]) / np.mean(preds[protected_test == 1])
else:
DI = 1
loggerdata(logger, "Mean ratio Check")
loggerdata(logger, str(DI))
if DI < self.mean_protected_prediction_ratio_minimum:
# Create a penalty proportional to the distance below the specified threshold
len_preds = len(preds)
num_penalty = min(len_preds, int((
self.mean_protected_prediction_ratio_minimum - DI) / self.mean_protected_prediction_ratio_minimum * len_preds))
preds[0:num_penalty] = penalty
loggerdata(logger, "num_penalty1")
loggerdata(logger, str(num_penalty), str(num_penalty / len(preds)))
self.is_train = False
return preds
def pre_get_model(self, X_shape=(1, 1), **kwargs):
self.prepare_xgb_predict(**self.params)
@staticmethod
def prepare_xgb_predict(**params):
"""
Gets xgboost ready for having pickled state on GPU or to use correct core count on CPU
:param params:
:return:
"""
import xgboost as xgb
model = xgb.XGBClassifier(**params)
X = np.array([[1, 2, 3, 4], [1, 3, 4, 2]])
y = np.array([1, 0])
model.fit(X=X, y=y)
return model