# main imports import numpy as np import pandas as pd import sys, os, argparse import subprocess import time import json # models imports from sklearn.utils import shuffle from sklearn.externals import joblib from sklearn.metrics import accuracy_score, f1_score, recall_score, roc_auc_score from sklearn.model_selection import cross_val_score from sklearn.model_selection import StratifiedKFold from sklearn.model_selection import train_test_split from keras.models import Sequential from keras.layers import Conv1D, MaxPooling1D from keras.layers import Activation, Dropout, Flatten, Dense, BatchNormalization from keras.wrappers.scikit_learn import KerasClassifier from keras import backend as K from keras.models import model_from_json # image processing imports from ipfml import processing from PIL import Image # modules imports sys.path.insert(0, '') # trick to enable import of main folder module import custom_config as cfg # variables and parameters threshold_map_folder = cfg.threshold_map_folder threshold_map_file_prefix = cfg.threshold_map_folder + "_" markdowns_folder = cfg.models_information_folder final_csv_model_comparisons = cfg.csv_model_comparisons_filename models_name = cfg.models_names_list zones = cfg.zones_indices current_dirpath = os.getcwd() def main(): kind_model = 'keras' model_ext = '' parser = argparse.ArgumentParser(description="Display SVD data of scene zone") parser.add_argument('--interval', type=str, help='Interval value to keep from svd', default='"0, 200"') parser.add_argument('--model', type=str, help='.joblib or .json file (sklearn or keras model)') parser.add_argument('--feature', type=str, help='Metric data choice', choices=cfg.features_choices_labels) parser.add_argument('--mode', type=str, help='Kind of normalization level wished', choices=cfg.normalization_choices) args = parser.parse_args() p_interval = list(map(int, args.interval.split(','))) p_model_file = args.model p_feature = args.feature p_mode = args.mode # call model and get global result in scenes begin, end = p_interval bash_cmd = "bash others/testModelByScene_maxwell.sh '" + str(begin) + "' '" + str(end) + "' '" + p_model_file + "' '" + p_mode + "' '" + p_feature + "'" print(bash_cmd) ## call command ## p = subprocess.Popen(bash_cmd, stdout=subprocess.PIPE, shell=True) (output, err) = p.communicate() ## Wait for result ## p_status = p.wait() if not os.path.exists(markdowns_folder): os.makedirs(markdowns_folder) # get model name to construct model if '.joblib' in p_model_file: kind_model = 'sklearn' model_ext = '.joblib' if '.json' in p_model_file: kind_model = 'keras' model_ext = '.json' md_model_path = os.path.join(markdowns_folder, p_model_file.split('/')[-1].replace(model_ext, '.md')) with open(md_model_path, 'w') as f: f.write(output.decode("utf-8")) # read each threshold_map information if exists model_map_info_path = os.path.join(threshold_map_folder, p_model_file.replace('saved_models/', '')) if not os.path.exists(model_map_info_path): f.write('\n\n No threshold map information') else: maps_files = os.listdir(model_map_info_path) # get all map information for t_map_file in maps_files: file_path = os.path.join(model_map_info_path, t_map_file) with open(file_path, 'r') as map_file: title_scene = t_map_file.replace(threshold_map_file_prefix, '') f.write('\n\n## ' + title_scene + '\n') content = map_file.readlines() # getting each map line information for line in content: f.write(line) f.close() # Keep model information to compare current_model_name = p_model_file.split('/')[-1].replace(model_ext, '') # Prepare writing in .csv file into results folder output_final_file_path = os.path.join(cfg.results_information_folder, final_csv_model_comparisons) output_final_file = open(output_final_file_path, "a") print(current_model_name) # reconstruct data filename for name in models_name: if name in current_model_name: data_filename = current_model_name current_data_file_path = os.path.join('data', data_filename) print("Current data file ") print(current_data_file_path) model_scores = [] ######################## # 1. Get and prepare data ######################## dataset_train = pd.read_csv(current_data_file_path + '.train', header=None, sep=";") dataset_test = pd.read_csv(current_data_file_path + '.test', header=None, sep=";") # default first shuffle of data dataset_train = shuffle(dataset_train) dataset_test = shuffle(dataset_test) # get dataset with equal number of classes occurences noisy_df_train = dataset_train[dataset_train.ix[:, 0] == 1] not_noisy_df_train = dataset_train[dataset_train.ix[:, 0] == 0] nb_noisy_train = len(noisy_df_train.index) noisy_df_test = dataset_test[dataset_test.ix[:, 0] == 1] not_noisy_df_test = dataset_test[dataset_test.ix[:, 0] == 0] nb_noisy_test = len(noisy_df_test.index) final_df_train = pd.concat([not_noisy_df_train[0:nb_noisy_train], noisy_df_train]) final_df_test = pd.concat([not_noisy_df_test[0:nb_noisy_test], noisy_df_test]) # shuffle data another time final_df_train = shuffle(final_df_train) final_df_test = shuffle(final_df_test) final_df_train_size = len(final_df_train.index) final_df_test_size = len(final_df_test.index) # use of the whole data set for training x_dataset_train = final_df_train.ix[:,1:] x_dataset_test = final_df_test.ix[:,1:] y_dataset_train = final_df_train.ix[:,0] y_dataset_test = final_df_test.ix[:,0] ####################### # 2. Getting model ####################### if kind_model == 'keras': with open(p_model_file, 'r') as f: json_model = json.load(f) model = model_from_json(json_model) model.load_weights(p_model_file.replace('.json', '.h5')) model.compile(loss='binary_crossentropy', optimizer='adam', features=['accuracy']) # reshape all input data x_dataset_train = np.array(x_dataset_train).reshape(len(x_dataset_train), end, 1) x_dataset_test = np.array(x_dataset_test).reshape(len(x_dataset_test), end, 1) if kind_model == 'sklearn': model = joblib.load(p_model_file) ####################### # 3. Fit model : use of cross validation to fit model ####################### if kind_model == 'keras': model.fit(x_dataset_train, y_dataset_train, validation_split=0.20, epochs=cfg.keras_epochs, batch_size=cfg.keras_batch) if kind_model == 'sklearn': model.fit(x_dataset_train, y_dataset_train) train_accuracy = cross_val_score(model, x_dataset_train, y_dataset_train, cv=5) ###################### # 4. Test : Validation and test dataset from .test dataset ###################### # we need to specify validation size to 20% of whole dataset val_set_size = int(final_df_train_size/3) test_set_size = val_set_size total_validation_size = val_set_size + test_set_size if final_df_test_size > total_validation_size: x_dataset_test = x_dataset_test[0:total_validation_size] y_dataset_test = y_dataset_test[0:total_validation_size] X_test, X_val, y_test, y_val = train_test_split(x_dataset_test, y_dataset_test, test_size=0.5, random_state=1) if kind_model == 'keras': y_test_model = model.predict_classes(X_test) y_val_model = model.predict_classes(X_val) y_train_model = model.predict_classes(x_dataset_train) train_accuracy = accuracy_score(y_dataset_train, y_train_model) if kind_model == 'sklearn': y_test_model = model.predict(X_test) y_val_model = model.predict(X_val) y_train_model = model.predict(x_dataset_train) val_accuracy = accuracy_score(y_val, y_val_model) test_accuracy = accuracy_score(y_test, y_test_model) train_f1 = f1_score(y_dataset_train, y_train_model) train_recall = recall_score(y_dataset_train, y_train_model) train_roc_auc = roc_auc_score(y_dataset_train, y_train_model) val_f1 = f1_score(y_val, y_val_model) val_recall = recall_score(y_val, y_val_model) val_roc_auc = roc_auc_score(y_val, y_val_model) test_f1 = f1_score(y_test, y_test_model) test_recall = recall_score(y_test, y_test_model) test_roc_auc = roc_auc_score(y_test, y_test_model) if kind_model == 'keras': # stats of all dataset all_x_data = np.concatenate([x_dataset_train, X_test, X_val]) all_y_data = np.concatenate([y_dataset_train, y_test, y_val]) all_y_model = model.predict_classes(all_x_data) if kind_model == 'sklearn': # stats of all dataset all_x_data = pd.concat([x_dataset_train, X_test, X_val]) all_y_data = pd.concat([y_dataset_train, y_test, y_val]) all_y_model = model.predict(all_x_data) all_accuracy = accuracy_score(all_y_data, all_y_model) all_f1_score = f1_score(all_y_data, all_y_model) all_recall_score = recall_score(all_y_data, all_y_model) all_roc_auc_score = roc_auc_score(all_y_data, all_y_model) # stats of dataset sizes total_samples = final_df_train_size + val_set_size + test_set_size model_scores.append(final_df_train_size) model_scores.append(val_set_size) model_scores.append(test_set_size) model_scores.append(final_df_train_size / total_samples) model_scores.append(val_set_size / total_samples) model_scores.append(test_set_size / total_samples) # add of scores model_scores.append(train_accuracy) model_scores.append(val_accuracy) model_scores.append(test_accuracy) model_scores.append(all_accuracy) model_scores.append(train_f1) model_scores.append(train_recall) model_scores.append(train_roc_auc) model_scores.append(val_f1) model_scores.append(val_recall) model_scores.append(val_roc_auc) model_scores.append(test_f1) model_scores.append(test_recall) model_scores.append(test_roc_auc) model_scores.append(all_f1_score) model_scores.append(all_recall_score) model_scores.append(all_roc_auc_score) # TODO : improve... # check if it's always the case... nb_zones = current_data_file_path.split('_')[7] final_file_line = current_model_name + '; ' + str(end - begin) + '; ' + str(begin) + '; ' + str(end) + '; ' + str(nb_zones) + '; ' + p_feature + '; ' + p_mode for s in model_scores: final_file_line += '; ' + str(s) output_final_file.write(final_file_line + '\n') if __name__== "__main__": main()