trust score imported

jiang18_trustscore/trustscore.py

@@ -0,0 +1,141 @@
+# Copyright 2018 Google LLC
+#
+# Licensed under the Apache License, Version 2.0 (the "License");
+# you may not use this file except in compliance with the License.
+# You may obtain a copy of the License at
+#
+#     https://www.apache.org/licenses/LICENSE-2.0
+#
+# Unless required by applicable law or agreed to in writing, software
+# distributed under the License is distributed on an "AS IS" BASIS,
+# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+# See the License for the specific language governing permissions and
+# limitations under the License.
+
+import numpy as np
+from sklearn.neighbors import KDTree, KNeighborsClassifier
+
+
+class TrustScore:
+    """
+    Trust Score: a measure of classifier uncertainty based on nearest neighbors.
+  """
+
+    def __init__(self, k=10, alpha=0.0, filtering="none", min_dist=1e-12):
+        """
+        k and alpha are the tuning parameters for the filtering,
+        filtering: method of filtering. option are "none", "density",
+        "uncertainty"
+        min_dist: some small number to mitigate possible division by 0.
+    """
+        self.k = k
+        self.filtering = filtering
+        self.alpha = alpha
+        self.min_dist = min_dist
+
+    def filter_by_density(self, X: np.array):
+        """Filter out points with low kNN density.
+
+    Args:
+    X: an array of sample points.
+
+    Returns:
+    A subset of the array without points in the bottom alpha-fraction of
+    original points of kNN density.
+    """
+        kdtree = KDTree(X)
+        knn_radii = kdtree.query(X, k=self.k)[0][:, -1]
+        eps = np.percentile(knn_radii, (1 - self.alpha) * 100)
+        return X[np.where(knn_radii <= eps)[0], :]
+
+    def filter_by_uncertainty(self, X: np.array, y: np.array):
+        """Filter out points with high label disagreement amongst its kNN neighbors.
+
+    Args:
+    X: an array of sample points.
+
+    Returns:
+    A subset of the array without points in the bottom alpha-fraction of
+    samples with highest disagreement amongst its k nearest neighbors.
+    """
+        neigh = KNeighborsClassifier(n_neighbors=self.k)
+        neigh.fit(X, y)
+        confidence = neigh.predict_proba(X)
+        cutoff = np.percentile(confidence, self.alpha * 100)
+        unfiltered_idxs = np.where(confidence >= cutoff)[0]
+        return X[unfiltered_idxs, :], y[unfiltered_idxs]
+
+    def fit(self, X: np.array, y: np.array):
+        """Initialize trust score precomputations with training data.
+
+    WARNING: assumes that the labels are 0-indexed (i.e.
+    0, 1,..., n_labels-1).
+
+    Args:
+    X: an array of sample points.
+    y: corresponding labels.
+    """
+
+        self.n_labels = np.max(y) + 1
+        self.kdtrees = [None] * self.n_labels
+        if self.filtering == "uncertainty":
+            X_filtered, y_filtered = self.filter_by_uncertainty(X, y)
+        for label in range(self.n_labels):
+            if self.filtering == "none":
+                X_to_use = X[np.where(y == label)[0]]
+                self.kdtrees[label] = KDTree(X_to_use)
+            elif self.filtering == "density":
+                X_to_use = self.filter_by_density(X[np.where(y == label)[0]])
+                self.kdtrees[label] = KDTree(X_to_use)
+            elif self.filtering == "uncertainty":
+                X_to_use = X_filtered[np.where(y_filtered == label)[0]]
+                self.kdtrees[label] = KDTree(X_to_use)
+
+            if len(X_to_use) == 0:
+                print(
+                    "Filtered too much or missing examples from a label! Please lower "
+                    "alpha or check data."
+                )
+
+    def get_score(self, X: np.array, y_pred: np.array):
+        """Compute the trust scores.
+
+    Given a set of points, determines the distance to each class.
+
+    Args:
+    X: an array of sample points.
+    y_pred: The predicted labels for these points.
+
+    Returns:
+    The trust score, which is ratio of distance to closest class that was not
+    the predicted class to the distance to the predicted class.
+    """
+        d = np.tile(None, (X.shape[0], self.n_labels))
+        for label_idx in range(self.n_labels):
+            d[:, label_idx] = self.kdtrees[label_idx].query(X, k=2)[0][:, -1]
+
+        sorted_d = np.sort(d, axis=1)
+        d_to_pred = d[range(d.shape[0]), y_pred]
+        d_to_closest_not_pred = np.where(
+            sorted_d[:, 0] != d_to_pred, sorted_d[:, 0], sorted_d[:, 1]
+        )
+        return d_to_closest_not_pred / (d_to_pred + self.min_dist)
+
+
+class KNNConfidence:
+    """Baseline which uses disagreement to kNN classifier.
+  """
+
+    def __init__(self, k=10):
+        self.k = k
+
+    def fit(self, X, y):
+        self.kdtree = KDTree(X)
+        self.y = y
+
+    def get_score(self, X, y_pred):
+        knn_idxs = self.kdtree.query(X, k=self.k)[1]
+        knn_outputs = self.y[knn_idxs]
+        return np.mean(
+            knn_outputs == np.transpose(np.tile(y_pred, (self.k, 1))), axis=1
+        )

jiang18_trustscore/trustscore_evaluation.py

@@ -0,0 +1,286 @@
+# Copyright 2018 Google LLC
+#
+# Licensed under the Apache License, Version 2.0 (the "License");
+# you may not use this file except in compliance with the License.
+# You may obtain a copy of the License at
+#
+#     https://www.apache.org/licenses/LICENSE-2.0
+#
+# Unless required by applicable law or agreed to in writing, software
+# distributed under the License is distributed on an "AS IS" BASIS,
+# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
+# See the License for the specific language governing permissions and
+# limitations under the License.
+
+import numpy as np
+from sklearn.model_selection import StratifiedShuffleSplit
+import matplotlib.pyplot as plt
+from sklearn.decomposition import PCA
+import matplotlib.cm as cm
+from sklearn.metrics import precision_recall_curve
+import tensorflow as tf
+
+from sklearn.linear_model import LogisticRegression
+from sklearn.svm import LinearSVC
+from sklearn.ensemble import RandomForestClassifier
+
+
+def run_logistic(X_train, y_train, X_test, y_test, get_training=False):
+  model = LogisticRegression()
+  model.fit(X_train, y_train)
+  y_pred = model.predict(X_test)
+  all_confidence = model.predict_proba(X_test)
+  confidences = all_confidence[range(len(y_pred)), y_pred]
+  if not get_training:
+    return y_pred, confidences
+  y_pred_training = model.predict(X_train)
+  all_confidence_training = model.predict_proba(X_train)
+  confidence_training = all_confidence_training[range(len(y_pred_training)),
+                                                y_pred_training]
+  return y_pred, confidences, y_pred_training, confidence_training
+
+
+def run_linear_svc(X_train, y_train, X_test, y_test, get_training=False):
+  model = LinearSVC()
+  model.fit(X_train, y_train)
+  y_pred = model.predict(X_test)
+  all_confidence = model.decision_function(X_test)
+  confidences = all_confidence[range(len(y_pred)), y_pred]
+  if not get_training:
+    return y_pred, confidences
+  y_pred_training = model.predict(X_train)
+  all_confidence_training = model.decision_function(X_train)
+  confidence_training = all_confidence_training[range(len(y_pred_training)),
+                                                y_pred_training]
+  return y_pred, confidences, y_pred_training, confidence_training
+
+
+def run_random_forest(X_train, y_train, X_test, y_test, get_training=False):
+  model = RandomForestClassifier()
+  model.fit(X_train, y_train)
+  y_pred = model.predict(X_test)
+  all_confidence = model.predict_proba(X_test)
+  confidences = all_confidence[range(len(y_pred)), y_pred]
+  if not get_training:
+    return y_pred, confidences
+  y_pred_training = model.predict(X_train)
+  all_confidence_training = model.predict_proba(X_train)
+  confidence_training = all_confidence_training[range(len(y_pred_training)),
+                                                y_pred_training]
+  return y_pred, confidences, y_pred_training, confidence_training
+
+
+def run_simple_NN(X,
+                  y,
+                  X_test,
+                  y_test,
+                  num_iter=10000,
+                  hidden_units=100,
+                  learning_rate=0.05,
+                  batch_size=100,
+                  display_steps=1000,
+                  n_layers=1,
+                  get_training=False):
+  """Run a NN with a single layer on some data.
+
+  Returns the predicted values as well as the confidences.
+  """
+  n_labels = np.max(y) + 1
+  n_features = X.shape[1]
+
+  x = tf.placeholder(tf.float32, [None, n_features])
+  y_ = tf.placeholder(tf.float32, [None, n_labels])
+
+  def simple_NN(input_placeholder, n_layers):
+
+    W_in = weight_variable([n_features, hidden_units])
+    b_in = bias_variable([hidden_units])
+    W_mid = [
+        weight_variable([hidden_units, hidden_units])
+        for i in range(n_layers - 1)
+    ]
+    b_mid = [bias_variable([hidden_units]) for i in range(n_layers - 1)]
+    W_out = weight_variable([hidden_units, n_labels])
+    b_out = bias_variable([n_labels])
+
+    layers = [tf.nn.relu(tf.matmul(input_placeholder, W_in) + b_in)]
+    for i in range(n_layers - 1):
+      layer = tf.nn.relu(tf.matmul(layers[-1], W_mid[i]) + b_mid[i])
+      layers.append(layer)
+
+    logits = tf.matmul(layers[-1], W_out) + b_out
+    return logits
+
+  NN_logits = simple_NN(x, n_layers)
+
+  cross_entropy = tf.reduce_mean(
+      tf.nn.softmax_cross_entropy_with_logits(labels=y_, logits=NN_logits))
+  train_step = tf.train.AdamOptimizer(learning_rate).minimize(cross_entropy)
+  correct_prediction = tf.equal(tf.argmax(NN_logits, 1), tf.argmax(y_, 1))
+  accuracy = tf.reduce_mean(tf.cast(correct_prediction, tf.float32))
+
+  def one_hot(ns):
+    return np.eye(n_labels)[ns]
+
+  y_onehot = one_hot(y)
+  y_test_onehot = one_hot(y_test)
+
+  with tf.Session() as sess:
+    sess.run(tf.global_variables_initializer())
+    for i in range(num_iter):
+      ns = np.random.randint(0, len(X), size=batch_size)
+      if (i + 1) % display_steps == 0:
+        train_accuracy = accuracy.eval(feed_dict={x: X, y_: y_onehot})
+        test_accuracy = accuracy.eval(feed_dict={x: X_test, y_: y_test_onehot})
+
+        print("step %d, training accuracy %g, test accuracy %g" %
+              (i + 1, train_accuracy, test_accuracy))
+      train_step.run(feed_dict={x: X[ns, :], y_: y_onehot[ns, :]})
+
+    testing_logits = NN_logits.eval(feed_dict={x: X_test})
+    testing_prediction = tf.argmax(NN_logits, 1).eval(feed_dict={x: X_test})
+    NN_softmax = tf.nn.softmax(NN_logits).eval(feed_dict={x: X_test})
+    testing_confidence_raw = tf.reduce_max(NN_softmax,
+                                           1).eval(feed_dict={x: X_test})
+
+    if not get_training:
+      return testing_prediction, testing_confidence_raw
+    training_prediction = tf.argmax(NN_logits, 1).eval(feed_dict={x: X})
+    NN_softmax = tf.nn.softmax(NN_logits).eval(feed_dict={x: X})
+    training_confidence_raw = tf.reduce_max(NN_softmax,
+                                            1).eval(feed_dict={x: X})
+    return testing_prediction, testing_confidence_raw, training_prediction, training_confidence_raw
+
+
+def plot_precision_curve(
+    extra_plot_title,
+    percentile_levels,
+    signal_names,
+    final_TPs,
+    final_stderrs,
+    final_misclassification,
+    model_name="Model",
+    colors=["blue", "darkorange", "brown", "red", "purple"],
+    legend_loc=None,
+    figure_size=None,
+    ylim=None):
+  if figure_size is not None:
+    plt.figure(figsize=figure_size)
+  title = "Precision Curve" if extra_plot_title == "" else extra_plot_title
+  plt.title(title, fontsize=20)
+  colors = colors + list(cm.rainbow(np.linspace(0, 1, len(final_TPs))))
+
+  plt.xlabel("Percentile level", fontsize=18)
+  plt.ylabel("Precision", fontsize=18)
+  for i, signal_name in enumerate(signal_names):
+    ls = "--" if ("Model" in signal_name) else "-"
+    plt.plot(
+        percentile_levels, final_TPs[i], ls, c=colors[i], label=signal_name)
+
+    plt.fill_between(
+        percentile_levels,
+        final_TPs[i] - final_stderrs[i],
+        final_TPs[i] + final_stderrs[i],
+        color=colors[i],
+        alpha=0.1)
+
+  if legend_loc is None:
+    if 0. in percentile_levels:
+      plt.legend(loc="lower right", fontsize=14)
+    else:
+      plt.legend(loc="upper left", fontsize=14)
+  else:
+    if legend_loc == "outside":
+      plt.legend(bbox_to_anchor=(1.04, 1), loc="upper left", fontsize=14)
+    else:
+      plt.legend(loc=legend_loc, fontsize=14)
+  if ylim is not None:
+    plt.ylim(*ylim)
+  model_acc = 100 * (1 - final_misclassification)
+  plt.axvline(x=model_acc, linestyle="dotted", color="black")
+  plt.show()
+
+
+def run_precision_recall_experiment_general(X,
+                                            y,
+                                            n_repeats,
+                                            percentile_levels,
+                                            trainer,
+                                            test_size=0.5,
+                                            extra_plot_title="",
+                                            signals=[],
+                                            signal_names=[],
+                                            predict_when_correct=False,
+                                            skip_print=False):
+
+  def get_stderr(L):
+    return np.std(L) / np.sqrt(len(L))
+
+  all_signal_names = ["Model Confidence"] + signal_names
+  all_TPs = [[[] for p in percentile_levels] for signal in all_signal_names]
+  misclassifications = []
+  sign = 1 if predict_when_correct else -1
+  sss = StratifiedShuffleSplit(
+      n_splits=n_repeats, test_size=test_size, random_state=0)
+  for train_idx, test_idx in sss.split(X, y):
+    X_train = X[train_idx, :]
+    y_train = y[train_idx]
+    X_test = X[test_idx, :]
+    y_test = y[test_idx]
+    testing_prediction, testing_confidence_raw = trainer(
+        X_train, y_train, X_test, y_test)
+    target_points = np.where(
+        testing_prediction == y_test)[0] if predict_when_correct else np.where(
+            testing_prediction != y_test)[0]
+
+    final_signals = [testing_confidence_raw]
+    for signal in signals:
+      signal.fit(X_train, y_train)
+      final_signals.append(signal.get_score(X_test, testing_prediction))
+
+    for p, percentile_level in enumerate(percentile_levels):
+      all_high_confidence_points = [
+          np.where(sign * signal >= np.percentile(sign *
+                                                  signal, percentile_level))[0]
+          for signal in final_signals
+      ]
+
+      if 0 in map(len, all_high_confidence_points):
+        continue
+      TP = [
+          len(np.intersect1d(high_confidence_points, target_points)) /
+          (1. * len(high_confidence_points))
+          for high_confidence_points in all_high_confidence_points
+      ]
+      for i in range(len(all_signal_names)):
+        all_TPs[i][p].append(TP[i])
+    misclassifications.append(len(target_points) / (1. * len(X_test)))
+
+  final_TPs = [[] for signal in all_signal_names]
+  final_stderrs = [[] for signal in all_signal_names]
+  for p, percentile_level in enumerate(percentile_levels):
+    for i in range(len(all_signal_names)):
+      final_TPs[i].append(np.mean(all_TPs[i][p]))
+      final_stderrs[i].append(get_stderr(all_TPs[i][p]))
+
+    if not skip_print:
+      print("Precision at percentile", percentile_level)
+      ss = ""
+      for i, signal_name in enumerate(all_signal_names):
+        ss += (signal_name + (": %.4f  " % final_TPs[i][p]))
+      print(ss)
+      print()
+
+  final_misclassification = np.mean(misclassifications)
+
+  if not skip_print:
+    print("Misclassification rate mean/std", np.mean(misclassifications),
+          get_stderr(misclassifications))
+
+  for i in range(len(all_signal_names)):
+    final_TPs[i] = np.array(final_TPs[i])
+    final_stderrs[i] = np.array(final_stderrs[i])
+
+  plot_precision_curve(extra_plot_title, percentile_levels, all_signal_names,
+                       final_TPs, final_stderrs, final_misclassification)
+  return (all_signal_names, final_TPs, final_stderrs, final_misclassification)

pyproject.toml

@@ -23,7 +23,7 @@ pytest-mock = "^3.11.1"
 pytest-cov = "^4.1.0"
 
 [tool.pytest.ini_options]
-addopts = "--cov=quacc"
+addopts = "--cov=quacc --capture=tee-sys"
 
 [build-system]
 requires = ["poetry-core"]

quacc/baseline.py

@@ -10,7 +10,7 @@ from garg22_ATC.ATC_helper import (
     get_max_conf,
 )
 import numpy as np
-
+from jiang18_trustscore.trustscore import TrustScore
 
 
 def kfcv(c_model: BaseEstimator, validation: LabelledCollection) -> Dict:
@@ -43,10 +43,11 @@ def ATC_MC(
     ATC_accuracy = get_ATC_acc(ATC_thres, test_scores)
 
     return {
-        "true_acc": 100*np.mean(np.argmax(test_probs, axis=-1) == test.y),
-        "pred_acc": ATC_accuracy
+        "true_acc": 100 * np.mean(np.argmax(test_probs, axis=-1) == test.y),
+        "pred_acc": ATC_accuracy,
     }
 
+
 def ATC_NE(
     c_model: BaseEstimator,
     validation: LabelledCollection,
@@ -71,7 +72,23 @@ def ATC_NE(
     ATC_accuracy = get_ATC_acc(ATC_thres, test_scores)
 
     return {
-        "true_acc": 100*np.mean(np.argmax(test_probs, axis=-1) == test.y),
-        "pred_acc": ATC_accuracy
+        "true_acc": 100 * np.mean(np.argmax(test_probs, axis=-1) == test.y),
+        "pred_acc": ATC_accuracy,
     }
 
+
+def trust_score(
+    c_model: BaseEstimator,
+    validation: LabelledCollection,
+    test: LabelledCollection,
+    predict_method="predict",
+):
+    c_model_predict = getattr(c_model, predict_method)
+
+    test_pred = c_model_predict(test.X)
+
+    trust_model = TrustScore()
+    trust_model.fit(validation.X, validation.y)
+
+    return trust_model.get_score(test.X, test_pred)
+

quacc/main.py

@@ -99,4 +99,4 @@ def estimate_binary():
 
 
 if __name__ == "__main__":
-    estimate_multiclass()
+    estimate_binary()

tests/test_baseline.py

@@ -1,12 +1,20 @@
 
 from sklearn.linear_model import LogisticRegression
-from quacc.baseline import kfcv
+from quacc.baseline import kfcv, trust_score
 from quacc.dataset import get_spambase
 
 
 class TestBaseline:
 
     def test_kfcv(self):
-        train, _, _ = get_spambase()
+        train, validation, _ = get_spambase()
         c_model = LogisticRegression()
-        assert "f1_score" in kfcv(c_model, train)
+        c_model.fit(train.X, train.y)
+        assert "f1_score" in kfcv(c_model, validation)
+
+    def test_trust_score(self):
+        train, validation, test = get_spambase()
+        c_model = LogisticRegression()
+        c_model.fit(train.X, train.y)
+        trustscore = trust_score(c_model, train, test)
+        assert len(trustscore) == len(test.y)