cart-elc

dimAll.py (2785B)

---

 import numpy as np
 import pandas as pd
 import decision_tree
 from sklearn.model_selection import KFold
 from sklearn.metrics import accuracy_score
 
 df = pd.read_csv('../../datasets/dim.csv')
 y = df[df.columns[-1]]
 df = df.drop(df.columns[-1], axis=1)
 X = df.to_numpy(dtype=np.float64)
 
 # Define hyperparameters
 depths = [1,2,3,4,5]
 criteria = ["gini", "twoing", "information gain"]
 lcs = [1,2]
 n_splits = 5
 n_trials = 10
 seed = 71
 
 # Store results
 accuracies = {lc: {depth: [] for depth in depths} for lc in lcs}
 treeSizes = {lc: {depth: [] for depth in depths} for lc in lcs}
 foldSizes = []
 foldAccuracies = []
 
 # Store results
 results = {criterion: {lc: {depth: [] for depth in depths} for lc in lcs} for criterion in criteria}
 tree_sizes = {criterion: {lc: {depth: [] for depth in depths} for lc in lcs} for criterion in criteria}
 
 for trial in range(n_trials):
     kf = KFold(n_splits=n_splits, shuffle=True, random_state=(trial + seed))
     
     for criterion in criteria:
         for lc in lcs:
             for depth in depths:
                 fold_accuracies = []
                 fold_sizes = []
                 
                 for train_index, test_index in kf.split(X):
                     X_train, X_test = X[train_index], X[test_index]
                     y_train, y_test = y[train_index], y[test_index]
                     
                     clf = decision_tree.ELCClassifier(depth, lc, 100, criterion)
                     clf.fit(X_train.ravel(), y_train.shape[0], y_train, int(X_train.size / y_train.shape[0]))
                     preds = clf.predict(X_test.ravel(), y_test.shape[0], int(X_test.size / y_test.shape[0]))
                     
                     fold_accuracies.append(100 * accuracy_score(y_pred=preds, y_true=y_test))
                     fold_sizes.append(clf.getSplits() + 1) # leaves not splits
                 
                 results[criterion][lc][depth].append(np.mean(fold_accuracies))
                 tree_sizes[criterion][lc][depth].append(np.mean(fold_sizes))
                                                                                  
 with open("resultsDim.txt", "w") as f:
     f.write("Results:\n")
     for criterion in criteria:
         f.write("\n")
         f.write(f"{criterion}:\n")
         for lc in lcs:
             for depth in depths:
                 avg_accuracy = np.mean(results[criterion][lc][depth])
                 std_accuracy = np.std(results[criterion][lc][depth])
                 avg_size = np.mean(tree_sizes[criterion][lc][depth])
                 std_size = np.std(tree_sizes[criterion][lc][depth])
                 
                 f.write(f"LCs: {lc}, Depth: {depth} Avg Accuracy: {avg_accuracy:.1f} (Std: {std_accuracy:.1f})")
                 f.write(f", Avg # of Leaves: {avg_size:.1f} (Std: {std_size:.1f})\n")