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| import numpy as np | |
| import matplotlib.pyplot as plt | |
| from threading import Thread | |
| from matplotlib.colors import ListedColormap | |
| from sklearn.datasets import make_moons, make_circles, make_classification | |
| from sklearn.datasets import make_blobs, make_circles, make_moons | |
| import gradio as gr | |
| import math | |
| from functools import partial | |
| import time | |
| import matplotlib | |
| from sklearn import svm | |
| from sklearn.datasets import make_moons, make_blobs | |
| from sklearn.covariance import EllipticEnvelope | |
| from sklearn.ensemble import IsolationForest | |
| from sklearn.neighbors import LocalOutlierFactor | |
| from sklearn.linear_model import SGDOneClassSVM | |
| from sklearn.kernel_approximation import Nystroem | |
| from sklearn.pipeline import make_pipeline | |
| def get_groundtruth_model(X, labels): | |
| # dummy model to show true label distribution | |
| class Dummy: | |
| def __init__(self, y): | |
| self.labels_ = labels | |
| return Dummy(labels) | |
| #### PLOT | |
| FIGSIZE = 10,10 | |
| figure = plt.figure(figsize=(25, 10)) | |
| def train_models(input_data, outliers_fraction, n_samples, clf_name): | |
| n_outliers = int(outliers_fraction * n_samples) | |
| n_inliers = n_samples - n_outliers | |
| blobs_params = dict(random_state=0, n_samples=n_inliers, n_features=2) | |
| NAME_CLF_MAPPING = {"Robust covariance": EllipticEnvelope(contamination=outliers_fraction), | |
| "One-Class SVM": svm.OneClassSVM(nu=outliers_fraction, kernel="rbf", gamma=0.1), | |
| "One-Class SVM (SGD)":make_pipeline( | |
| Nystroem(gamma=0.1, random_state=42, n_components=150), | |
| SGDOneClassSVM( | |
| nu=outliers_fraction, | |
| shuffle=True, | |
| fit_intercept=True, | |
| random_state=42, | |
| tol=1e-6, | |
| ), | |
| ), | |
| "Isolation Forest": IsolationForest(contamination=outliers_fraction, random_state=42), | |
| "Local Outlier Factor": LocalOutlierFactor(n_neighbors=35, contamination=outliers_fraction), | |
| } | |
| DATA_MAPPING = { | |
| "Central Blob":make_blobs(centers=[[0, 0], [0, 0]], cluster_std=0.5, **blobs_params)[0], | |
| "Two Blobs": make_blobs(centers=[[2, 2], [-2, -2]], cluster_std=[0.5, 0.5], **blobs_params)[0], | |
| "Blob with Noise": make_blobs(centers=[[2, 2], [-2, -2]], cluster_std=[1.5, 0.3], **blobs_params)[0], | |
| "Moons": 4.0 | |
| * ( | |
| make_moons(n_samples=n_samples, noise=0.05, random_state=0)[0] | |
| - np.array([0.5, 0.25]) | |
| ), | |
| "Noise": 14.0 * (np.random.RandomState(42).rand(n_samples, 2) - 0.5), | |
| } | |
| DATASETS = [ | |
| make_blobs(centers=[[0, 0], [0, 0]], cluster_std=0.5, **blobs_params)[0], | |
| make_blobs(centers=[[2, 2], [-2, -2]], cluster_std=[0.5, 0.5], **blobs_params)[0], | |
| make_blobs(centers=[[2, 2], [-2, -2]], cluster_std=[1.5, 0.3], **blobs_params)[0], | |
| 4.0 | |
| * ( | |
| make_moons(n_samples=n_samples, noise=0.05, random_state=0)[0] | |
| - np.array([0.5, 0.25]) | |
| ), | |
| 14.0 * (np.random.RandomState(42).rand(n_samples, 2) - 0.5), | |
| ] | |
| xx, yy = np.meshgrid(np.linspace(-7, 7, 150), np.linspace(-7, 7, 150)) | |
| clf = NAME_CLF_MAPPING[clf_name] | |
| plt.figure(figsize=(len(NAME_CLF_MAPPING) * 2 + 4, 12.5)) | |
| plot_num = 1 | |
| rng = np.random.RandomState(42) | |
| X = DATA_MAPPING[input_data] | |
| X = np.concatenate([X, rng.uniform(low=-6, high=6, size=(n_outliers, 2))], axis=0) | |
| t0 = time.time() | |
| clf.fit(X) | |
| t1 = time.time() | |
| # fit the data and tag outliers | |
| if clf_name == "Local Outlier Factor": | |
| y_pred = clf.fit_predict(X) | |
| else: | |
| y_pred = clf.fit(X).predict(X) | |
| # plot the levels lines and the points | |
| if clf_name != "Local Outlier Factor": | |
| Z = clf.predict(np.c_[xx.ravel(), yy.ravel()]) | |
| Z = Z.reshape(xx.shape) | |
| plt.contour(xx, yy, Z, levels=[0], linewidths=10, colors="black") | |
| colors = np.array(["#377eb8", "#ff7f00"]) | |
| plt.scatter(X[:, 0], X[:, 1], s=100, color=colors[(y_pred + 1) // 2]) | |
| plt.xlim(-7, 7) | |
| plt.ylim(-7, 7) | |
| plt.xticks(()) | |
| plt.yticks(()) | |
| plt.text( | |
| 0.99, | |
| 0.01, | |
| ("%.2fs" % (t1 - t0)).lstrip("0"), | |
| transform=plt.gca().transAxes, | |
| size=60, | |
| horizontalalignment="right", | |
| ) | |
| plot_num += 1 | |
| return plt | |
| description = "Learn how different anomaly detection algorithms perform in different datasets." | |
| def iter_grid(n_rows, n_cols): | |
| # create a grid using gradio Block | |
| for _ in range(n_rows): | |
| with gr.Row(): | |
| for _ in range(n_cols): | |
| with gr.Column(): | |
| yield | |
| title = "🕵️♀️ compare anomaly detection algorithms 🕵️♂️" | |
| with gr.Blocks() as demo: | |
| gr.Markdown(f"## {title}") | |
| gr.Markdown(description) | |
| input_models = ["Robust covariance","One-Class SVM","One-Class SVM (SGD)","Isolation Forest", | |
| "Local Outlier Factor"] | |
| input_data = gr.Radio( | |
| choices=["Central Blob", "Two Blobs", "Blob with Noise", "Moons", "Noise"], | |
| value="Moons" | |
| ) | |
| n_samples = gr.Slider(minimum=100, maximum=500, step=25, label="Number of Samples") | |
| outliers_fraction = gr.Slider(minimum=0.1, maximum=0.9, step=0.1, label="Fraction of Outliers") | |
| counter = 0 | |
| for _ in iter_grid(5, 5): | |
| if counter >= len(input_models): | |
| break | |
| input_model = input_models[counter] | |
| plot = gr.Plot(label=input_model) | |
| fn = partial(train_models, clf_name=input_model) | |
| input_data.change(fn=fn, inputs=[input_data, outliers_fraction, n_samples], outputs=plot) | |
| n_samples.change(fn=fn, inputs=[input_data, outliers_fraction, n_samples], outputs=plot) | |
| outliers_fraction.change(fn=fn, inputs=[input_data, outliers_fraction, n_samples], outputs=plot) | |
| counter += 1 | |
| demo.launch(enable_queue=True, debug=True) | |