def test_random_walk(): """Random input test for the Simple Random Walk kernel.""" train, test = generate_dataset(n_graphs=100, r_vertices=(10, 20), r_connectivity=(0.4, 0.8), r_weight_edges=(0.01, 12.0), n_graphs_test=40, random_state=rs, features=None) rw_kernel = RandomWalk(verbose=verbose, normalize=normalize) try: rw_kernel.fit_transform(train) rw_kernel.transform(test) assert True except Exception as exception: assert False, exception
# Compute the classification accuracy # hint: use the accuracy_score function of scikit-learn ################## # your code here # print(accuracy_score(y_test, y_pred)) ################## # Use the random walk kernel and the pyramid match graph kernel to perform classification ################## # your code here # gk1 = RandomWalk() K_train1 = gk1.fit_transform(G_train) K_test1 = gk1.transform(G_test) clf1 = SVC(kernel='precomputed', C=1) # Initialize SVM clf1.fit(K_train, y_train) # Train SVM y_pred1 = clf1.predict(K_test) # Predict print(accuracy_score(y_test, y_pred1)) ################## ############## Question 3 # Classify the graphs of a real-world dataset using graph kernels # Load the MUTAG dataset # hint: use the fetch_dataset function of GraKeL ##################