understanding montecarlo sampling
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@ -16,68 +16,68 @@ if __name__ == '__main__':
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qp.environ['N_JOBS'] = -1
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n_bags_val = 250
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n_bags_test = 1000
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optim = 'mae'
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result_dir = f'results/binary/{optim}'
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for optim in ['mae', 'mrae']:
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result_dir = f'results/binary/{optim}'
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os.makedirs(result_dir, exist_ok=True)
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os.makedirs(result_dir, exist_ok=True)
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for method in BIN_METHODS:
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for method in BIN_METHODS:
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print('Init method', method)
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print('Init method', method)
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global_result_path = f'{result_dir}/{method}'
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global_result_path = f'{result_dir}/{method}'
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if not os.path.exists(global_result_path + '.csv'):
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with open(global_result_path + '.csv', 'wt') as csv:
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csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
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if not os.path.exists(global_result_path + '.csv'):
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with open(global_result_path + '.csv', 'wt') as csv:
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csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
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with open(global_result_path + '.csv', 'at') as csv:
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with open(global_result_path + '.csv', 'at') as csv:
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for dataset in qp.datasets.UCI_DATASETS:
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if dataset in ['acute.a', 'acute.b', 'iris.1']: continue # , 'pageblocks.5', 'spambase', 'wdbc']: continue
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for dataset in qp.datasets.UCI_DATASETS:
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if dataset in ['acute.a', 'acute.b', 'iris.1']: continue # , 'pageblocks.5', 'spambase', 'wdbc']: continue
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print('init', dataset)
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print('init', dataset)
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local_result_path = global_result_path + '_' + dataset
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if os.path.exists(local_result_path + '.dataframe'):
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print(f'result file {local_result_path}.dataframe already exist; skipping')
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continue
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local_result_path = global_result_path + '_' + dataset
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if os.path.exists(local_result_path + '.dataframe'):
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print(f'result file {local_result_path}.dataframe already exist; skipping')
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continue
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with qp.util.temp_seed(SEED):
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with qp.util.temp_seed(SEED):
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param_grid, quantifier = new_method(method, max_iter=3000)
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param_grid, quantifier = new_method(method, max_iter=3000)
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data = qp.datasets.fetch_UCIDataset(dataset)
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data = qp.datasets.fetch_UCIDataset(dataset)
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# model selection
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train, test = data.train_test
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train, val = train.split_stratified()
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# model selection
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train, test = data.train_test
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train, val = train.split_stratified()
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protocol = UPP(val, repeats=n_bags_val)
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modsel = GridSearchQ(
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quantifier, param_grid, protocol, refit=True, n_jobs=-1, verbose=1, error=optim
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)
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protocol = UPP(val, repeats=n_bags_val)
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modsel = GridSearchQ(
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quantifier, param_grid, protocol, refit=True, n_jobs=-1, verbose=1, error=optim
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)
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try:
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modsel.fit(train)
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try:
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modsel.fit(train)
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print(f'best params {modsel.best_params_}')
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print(f'best score {modsel.best_score_}')
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pickle.dump(
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(modsel.best_params_, modsel.best_score_,),
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open(f'{local_result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
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print(f'best params {modsel.best_params_}')
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print(f'best score {modsel.best_score_}')
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pickle.dump(
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(modsel.best_params_, modsel.best_score_,),
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open(f'{local_result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
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quantifier = modsel.best_model()
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except:
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print('something went wrong... reporting CC')
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quantifier = qp.method.aggregative.CC(LR()).fit(train)
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quantifier = modsel.best_model()
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except:
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print('something went wrong... reporting CC')
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quantifier = qp.method.aggregative.CC(LR()).fit(train)
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protocol = UPP(test, repeats=n_bags_test)
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report = qp.evaluation.evaluation_report(quantifier, protocol, error_metrics=['mae', 'mrae', 'kld'],
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verbose=True)
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report.to_csv(f'{local_result_path}.dataframe')
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means = report.mean()
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csv.write(f'{method}\t{data.name}\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
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csv.flush()
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protocol = UPP(test, repeats=n_bags_test)
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report = qp.evaluation.evaluation_report(quantifier, protocol, error_metrics=['mae', 'mrae', 'kld'],
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verbose=True)
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report.to_csv(f'{local_result_path}.dataframe')
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means = report.mean()
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csv.write(f'{method}\t{data.name}\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
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csv.flush()
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show_results(global_result_path)
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show_results(global_result_path)
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@ -6,8 +6,8 @@ from distribution_matching.method_dirichlety import DIRy
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from sklearn.linear_model import LogisticRegression
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METHODS = ['ACC', 'PACC', 'HDy-OvA', 'DIR', 'DM', 'KDEy-DM', 'EMQ', 'KDEy-ML']
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BIN_METHODS = ['ACC', 'PACC', 'HDy', 'DIR', 'DM', 'KDEy-DM', 'EMQ', 'KDEy-ML']
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METHODS = ['KDEy-DMjs', 'ACC', 'PACC', 'HDy-OvA', 'DIR', 'DM', 'KDEy-DM', 'EMQ', 'KDEy-ML'] #, 'KDEy-DMhd2'] #, 'KDEy-DMhd2', 'DM-HD']
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BIN_METHODS = [x.replace('-OvA', '') for x in METHODS]
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hyper_LR = {
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@ -57,10 +57,30 @@ def new_method(method, **lr_kwargs):
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param_grid = {**method_params, **hyper_LR}
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quantifier = DistributionMatching(lr)
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elif method in ['KDE-DMkld']:
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# experimental
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elif method in ['KDEy-DMkld']:
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method_params = {'bandwidth': np.linspace(0.01, 0.2, 20)}
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param_grid = {**method_params, **hyper_LR}
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quantifier = KDEy(lr, target='min_divergence', divergence='KLD', montecarlo_trials=5000, val_split=10)
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elif method in ['KDEy-DMhd']:
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method_params = {'bandwidth': np.linspace(0.01, 0.2, 20)}
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param_grid = {**method_params, **hyper_LR}
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quantifier = KDEy(lr, target='min_divergence', divergence='HD', montecarlo_trials=5000, val_split=10)
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elif method in ['KDEy-DMhd2']:
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method_params = {'bandwidth': np.linspace(0.01, 0.2, 20)}
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param_grid = {**method_params, **hyper_LR}
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quantifier = KDEy(lr, target='min_divergence_uniform', divergence='HD', montecarlo_trials=5000, val_split=10)
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elif method in ['KDEy-DMjs']:
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method_params = {'bandwidth': np.linspace(0.01, 0.2, 20)}
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param_grid = {**method_params, **hyper_LR}
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quantifier = KDEy(lr, target='min_divergence_uniform', divergence='JS', montecarlo_trials=5000, val_split=10)
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elif method == 'DM-HD':
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method_params = {
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'nbins': [4,8,16,32],
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'val_split': [10, 0.4],
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}
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param_grid = {**method_params, **hyper_LR}
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quantifier = DistributionMatching(lr, divergence='HD')
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else:
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raise NotImplementedError('unknown method', method)
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@ -13,48 +13,49 @@ if __name__ == '__main__':
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qp.environ['SAMPLE_SIZE'] = qp.datasets.LEQUA2022_SAMPLE_SIZE['T1B']
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qp.environ['N_JOBS'] = -1
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optim = 'mrae'
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result_dir = f'results/lequa/{optim}'
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for optim in ['mae', 'mrae']:
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os.makedirs(result_dir, exist_ok=True)
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result_dir = f'results/lequa/{optim}'
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for method in METHODS:
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print('Init method', method)
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os.makedirs(result_dir, exist_ok=True)
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result_path = f'{result_dir}/{method}'
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if os.path.exists(result_path+'.csv'):
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print(f'file {result_path}.csv already exist; skipping')
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continue
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for method in METHODS:
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with open(result_path+'.csv', 'wt') as csv:
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csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
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print('Init method', method)
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dataset = 'T1B'
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train, val_gen, test_gen = qp.datasets.fetch_lequa2022(dataset)
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print(f'init {dataset} #instances: {len(train)}')
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param_grid, quantifier = new_method(method)
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result_path = f'{result_dir}/{method}'
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if param_grid is not None:
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modsel = GridSearchQ(quantifier, param_grid, protocol=val_gen, refit=False, n_jobs=-1, verbose=1, error=optim)
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if os.path.exists(result_path+'.csv'):
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print(f'file {result_path}.csv already exist; skipping')
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continue
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modsel.fit(train)
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print(f'best params {modsel.best_params_}')
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print(f'best score {modsel.best_score_}')
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pickle.dump(
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(modsel.best_params_, modsel.best_score_,),
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open(f'{result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
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with open(result_path+'.csv', 'wt') as csv:
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csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
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quantifier = modsel.best_model()
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else:
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print('debug mode... skipping model selection')
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quantifier.fit(train)
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dataset = 'T1B'
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train, val_gen, test_gen = qp.datasets.fetch_lequa2022(dataset)
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print(f'init {dataset} #instances: {len(train)}')
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param_grid, quantifier = new_method(method)
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report = qp.evaluation.evaluation_report(quantifier, protocol=test_gen, error_metrics=['mae', 'mrae', 'kld'], verbose=True)
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means = report.mean()
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report.to_csv(result_path+'.dataframe')
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csv.write(f'{method}\tLeQua-T1B\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
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csv.flush()
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if param_grid is not None:
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modsel = GridSearchQ(quantifier, param_grid, protocol=val_gen, refit=False, n_jobs=-1, verbose=1, error=optim)
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show_results(result_path)
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modsel.fit(train)
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print(f'best params {modsel.best_params_}')
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print(f'best score {modsel.best_score_}')
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pickle.dump(
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(modsel.best_params_, modsel.best_score_,),
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open(f'{result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
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quantifier = modsel.best_model()
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else:
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print('debug mode... skipping model selection')
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quantifier.fit(train)
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report = qp.evaluation.evaluation_report(quantifier, protocol=test_gen, error_metrics=['mae', 'mrae', 'kld'], verbose=True)
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means = report.mean()
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report.to_csv(result_path+'.dataframe')
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csv.write(f'{method}\tLeQua-T1B\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
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csv.flush()
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show_results(result_path)
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@ -27,7 +27,7 @@ class KDEy(AggregativeProbabilisticQuantifier):
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BANDWIDTH_METHOD = ['auto', 'scott', 'silverman']
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ENGINE = ['scipy', 'sklearn', 'statsmodels']
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TARGET = ['min_divergence', 'max_likelihood']
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TARGET = ['min_divergence', 'min_divergence_uniform', 'max_likelihood']
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def __init__(self, classifier: BaseEstimator, val_split=0.4, divergence: Union[str, Callable]='L2',
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bandwidth='scott', engine='sklearn', target='min_divergence', n_jobs=None, random_state=0, montecarlo_trials=1000):
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@ -35,7 +35,7 @@ class KDEy(AggregativeProbabilisticQuantifier):
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f'unknown bandwidth_method, valid ones are {KDEy.BANDWIDTH_METHOD}'
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assert engine in KDEy.ENGINE, f'unknown engine, valid ones are {KDEy.ENGINE}'
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assert target in KDEy.TARGET, f'unknown target, valid ones are {KDEy.TARGET}'
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assert divergence=='KLD', 'in this version I will only allow KLD as a divergence'
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assert divergence in ['KLD', 'HD', 'JS'], 'in this version I will only allow KLD or squared HD as a divergence'
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self.classifier = classifier
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self.val_split = val_split
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self.divergence = divergence
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@ -118,7 +118,6 @@ class KDEy(AggregativeProbabilisticQuantifier):
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self.classifier, y, posteriors, classes, class_count = cross_generate_predictions(
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data, self.classifier, val_split, probabilistic=True, fit_classifier=fit_classifier, n_jobs=self.n_jobs
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)
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print('classifier fit done')
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if self.bandwidth == 'auto':
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self.bandwidth = self.search_bandwidth_maxlikelihood(posteriors, y)
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@ -126,21 +125,22 @@ class KDEy(AggregativeProbabilisticQuantifier):
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self.val_densities = [self.get_kde_function(posteriors[y == cat]) for cat in range(data.n_classes)]
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self.val_posteriors = posteriors
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if self.target == 'min_divergence_depr':
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if self.target == 'min_divergence_uniform':
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self.samples = qp.functional.uniform_prevalence_sampling(n_classes=data.n_classes, size=self.montecarlo_trials)
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self.sample_densities = [self.pdf(kde_i, self.samples) for kde_i in self.val_densities]
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if self.target == 'min_divergence':
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elif self.target == 'min_divergence':
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self.class_samples = [kde_i.sample(self.montecarlo_trials, random_state=self.random_state) for kde_i in self.val_densities]
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self.class_sample_densities = {}
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for ci, samples_i in enumerate(self.class_samples):
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self.class_sample_densities[ci] = np.asarray([self.pdf(kde_j, samples_i) for kde_j in self.val_densities]).T
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print('kde fit done')
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return self
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def aggregate(self, posteriors: np.ndarray):
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if self.target == 'min_divergence':
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return self._target_divergence(posteriors)
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elif self.target == 'min_divergence_uniform':
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return self._target_divergence_uniform(posteriors)
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elif self.target == 'max_likelihood':
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return self._target_likelihood(posteriors)
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else:
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@ -170,6 +170,42 @@ class KDEy(AggregativeProbabilisticQuantifier):
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# r = optimize.minimize(match, x0=uniform_distribution, method='SLSQP', bounds=bounds, constraints=constraints)
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# return r.x
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def _target_divergence_uniform(self, posteriors):
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# in this variant we evaluate the divergence using a Montecarlo approach
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n_classes = len(self.val_densities)
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test_kde = self.get_kde_function(posteriors)
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test_likelihood = self.pdf(test_kde, self.samples)
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def f_squared_hellinger(t):
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return (np.sqrt(t) - 1)**2
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def f_jensen_shannon(t):
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return -(t+1)*np.log((t+1)/2) + t*np.log(t)
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def fdivergence(pi, qi, f, eps=1e-10):
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spi = pi+eps
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sqi = qi+eps
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return np.mean(f(spi/sqi)*sqi)
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if self.divergence.lower() == 'hd':
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f = f_squared_hellinger
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elif self.divergence.lower() == 'js':
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f = f_jensen_shannon
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def match(prev):
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val_likelihood = sum(prev_i * dens_i for prev_i, dens_i in zip (prev, self.sample_densities))
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return fdivergence(val_likelihood, test_likelihood, f)
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# the initial point is set as the uniform distribution
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uniform_distribution = np.full(fill_value=1 / n_classes, shape=(n_classes,))
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# solutions are bounded to those contained in the unit-simplex
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bounds = tuple((0, 1) for _ in range(n_classes)) # values in [0,1]
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constraints = ({'type': 'eq', 'fun': lambda x: 1 - sum(x)}) # values summing up to 1
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r = optimize.minimize(match, x0=uniform_distribution, method='SLSQP', bounds=bounds, constraints=constraints)
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return r.x
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def _target_divergence(self, posteriors):
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# in this variant we evaluate the divergence using a Montecarlo approach
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n_classes = len(self.val_densities)
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@ -184,6 +220,18 @@ class KDEy(AggregativeProbabilisticQuantifier):
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smooth_qi = qi+eps
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return np.mean(np.log(smooth_pi / smooth_qi))
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def squared_hellinger(pi, qi, eps=1e-8):
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smooth_pi = pi + eps
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smooth_qi = qi + eps
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return np.mean((np.sqrt(smooth_pi/smooth_qi)-1)**2)
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# todo: this will fail when self.divergence is a callable, and is not the right place to do it anyway
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if self.divergence.lower() == 'kld':
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fdivergence = kld_monte
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elif self.divergence.lower() == 'hd':
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fdivergence = squared_hellinger
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def match(prev):
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# choose the samples according to the prevalence vector
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# e.g., prev = [0.5, 0.3, 0.2] will draw 50% from KDE_0, 30% from KDE_1, and 20% from KDE_2
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@ -202,7 +250,7 @@ class KDEy(AggregativeProbabilisticQuantifier):
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test_likelihood = np.concatenate(
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[samples_i[:num_i] for samples_i, num_i in zip(test_densities_per_class, num_variates_per_class)]
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)
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return kld_monte(val_likelihood, test_likelihood)
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return fdivergence(val_likelihood, test_likelihood)
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# the initial point is set as the uniform distribution
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uniform_distribution = np.full(fill_value=1 / n_classes, shape=(n_classes,))
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@ -246,4 +294,5 @@ class KDEy(AggregativeProbabilisticQuantifier):
|
|||
#print('searching for alpha')
|
||||
r = optimize.minimize(neg_loglikelihood, x0=uniform_distribution, method='SLSQP', bounds=bounds, constraints=constraints)
|
||||
#print('[optimization ended]')
|
||||
return r.x
|
||||
return r.x
|
||||
|
||||
|
|
|
@ -1,49 +1,21 @@
|
|||
Cosa fundamental:
|
||||
KDE se puede usar para generar 2 distribuciones (una, es un mixture model de KDEs en train condicionados a cada clase,
|
||||
y el otro es un KDE en test), de las que luego se calculará la divergencia (objetivo a minimizar). Otra opción es
|
||||
generar solo una distribución (mixture model de train) y tomar la likelihood de los puntos de test como objetivo
|
||||
a maximizar.
|
||||
1.- No se si sería más facil tomar r=uniforme, y no r=mixture model, simplifica mucho el sampling y tal vez incluso produzca menos error
|
||||
2.- Por ahora tengo KLD y HD:
|
||||
- para KLD no he entendido si tengo que añadir el -x + y
|
||||
3.- Se puede poner la topsoe como una f-divergence?
|
||||
La topsoe parece que es 2 veces la jensen-shannon divergence, o sea
|
||||
topsoe(p,q) = kld(p|m) + kld(q|m), con m = (p+q)/2
|
||||
4.- Se puede poner la Wasserstein como una f-divergence?
|
||||
5.- En general, qué relación hay con las "distancias"?
|
||||
|
||||
- echar un ojo a los hyperparametros
|
||||
- hacer dibujitos
|
||||
- estudiar el caso en que el target es minimizar una divergencia. Posibilidades:
|
||||
- evaluar los puntos de test solo
|
||||
- evaluar un APP sobre el simplexo?
|
||||
- evaluar un UPP sobre el simplexo? (=Montecarlo)
|
||||
- qué divergencias? HD, topsoe, L1?
|
||||
- tampoco estoy evaluando en modo kfcv creo...
|
||||
|
||||
1) sacar lequa-kfcv y todos los kfcv que puedan tener sentido en tweets
|
||||
2) implementar el auto
|
||||
- optimización interna para likelihood [ninguno parece funcionar bien]
|
||||
- de todo (e.g., todo el training)?
|
||||
- independiente para cada conjunto etiquetado? (e.g., positivos, negativos, neutros, y test)
|
||||
- optimización como un parámetro GridSearchQ
|
||||
6) optimizar kernel? optimizar distancia?
|
||||
7) KDE de sklearn o multivariate KDE de statsmodel? ver también qué es esto (parece que da P(Y|X) o sea que podría
|
||||
eliminar el clasificador?):
|
||||
https://www.statsmodels.org/dev/_modules/statsmodels/nonparametric/kernel_density.html#KDEMultivariateConditional
|
||||
8) quitar la ultima dimension en sklearn también? No veo porqué
|
||||
9) optimizar para RAE en vez de AE? No va bien...
|
||||
10) Definir un clasificador que devuelva, para cada clase, una posterior como la likelihood en la class-conditional KDE dividida
|
||||
por la likelihood en en todas las clases (como propone Juanjo) y meterlo en EMD. Hacer al contario: re-calibrar con
|
||||
EMD y meterlo en KDEy
|
||||
11) KDEx?
|
||||
12) Dirichlet (el método DIR) habría que arreglarlo y mostrar resultados...
|
||||
13) Test estadisticos.
|
||||
|
||||
Notas:
|
||||
estoy probando a reemplazar el target max_likelihood con un min_divergence:
|
||||
- como la divergencia entre dos KDEs ahora es en el espacio continuo, no es facil como obtener. Estoy probando
|
||||
con una evaluación en test, pero el problema es que es overconfident con respecto a la que ha sido obtenida en test.
|
||||
Otra opción es un MonteCarlo que es lo que estoy probando ahora. Para este experimento he quitado la model selection
|
||||
del clasificador, y estoy dejando solo la que hace con el bandwidth por agilizarlo. Los resultados KDE-nomonte son un
|
||||
max_likelihood en igualdad de condiciones (solo bandwidth), KDE-monte1 es un montecarlo con HD a 1000 puntos, y KDE-monte2
|
||||
es lo mismo pero con 5000 puntos; ambos funcionan mal. KDE-monte1 y KDE-monte2 los voy a borrar.
|
||||
Ahora estoy probando con KDE-monte3, lo mismo pero con una L2 como
|
||||
divergencia. Parece mucho más parecido a KDE-nomonte (pero sigue siendo algo peor)
|
||||
- probar con más puntos (KDE-monte4 es a 5000 puntos)
|
||||
- habría que probar con topsoe (KDE-monte5)
|
||||
- probar con optimización del LR (KDE-monte6 y con kfcv)
|
||||
- probar con L1 en vez de L2 (KDE-monte7 con 5000 puntos y sin LR)
|
||||
- tal vez habría que probar con la L2, que funciona bien, en el min_divergence que evaluaba en test, o test+train
|
|
@ -15,70 +15,71 @@ if __name__ == '__main__':
|
|||
qp.environ['N_JOBS'] = -1
|
||||
n_bags_val = 250
|
||||
n_bags_test = 1000
|
||||
optim = 'mae'
|
||||
result_dir = f'results/tweet/{optim}'
|
||||
for optim in ['mae', 'mrae']:
|
||||
|
||||
os.makedirs(result_dir, exist_ok=True)
|
||||
result_dir = f'results/tweet/{optim}'
|
||||
|
||||
for method in METHODS:
|
||||
|
||||
print('Init method', method)
|
||||
os.makedirs(result_dir, exist_ok=True)
|
||||
|
||||
global_result_path = f'{result_dir}/{method}'
|
||||
|
||||
if not os.path.exists(global_result_path+'.csv'):
|
||||
with open(global_result_path+'.csv', 'wt') as csv:
|
||||
csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
|
||||
for method in METHODS:
|
||||
|
||||
with open(global_result_path+'.csv', 'at') as csv:
|
||||
# four semeval dataset share the training, so it is useless to optimize hyperparameters four times;
|
||||
# this variable controls that the mod sel has already been done, and skip this otherwise
|
||||
semeval_trained = False
|
||||
print('Init method', method)
|
||||
|
||||
for dataset in qp.datasets.TWITTER_SENTIMENT_DATASETS_TEST:
|
||||
print('init', dataset)
|
||||
global_result_path = f'{result_dir}/{method}'
|
||||
|
||||
local_result_path = global_result_path + '_' + dataset
|
||||
if os.path.exists(local_result_path+'.dataframe'):
|
||||
print(f'result file {local_result_path}.dataframe already exist; skipping')
|
||||
continue
|
||||
|
||||
with qp.util.temp_seed(SEED):
|
||||
if not os.path.exists(global_result_path+'.csv'):
|
||||
with open(global_result_path+'.csv', 'wt') as csv:
|
||||
csv.write(f'Method\tDataset\tMAE\tMRAE\tKLD\n')
|
||||
|
||||
is_semeval = dataset.startswith('semeval')
|
||||
with open(global_result_path+'.csv', 'at') as csv:
|
||||
# four semeval dataset share the training, so it is useless to optimize hyperparameters four times;
|
||||
# this variable controls that the mod sel has already been done, and skip this otherwise
|
||||
semeval_trained = False
|
||||
|
||||
if not is_semeval or not semeval_trained:
|
||||
for dataset in qp.datasets.TWITTER_SENTIMENT_DATASETS_TEST:
|
||||
print('init', dataset)
|
||||
|
||||
param_grid, quantifier = new_method(method)
|
||||
local_result_path = global_result_path + '_' + dataset
|
||||
if os.path.exists(local_result_path+'.dataframe'):
|
||||
print(f'result file {local_result_path}.dataframe already exist; skipping')
|
||||
continue
|
||||
|
||||
# model selection
|
||||
data = qp.datasets.fetch_twitter(dataset, min_df=3, pickle=True, for_model_selection=True)
|
||||
with qp.util.temp_seed(SEED):
|
||||
|
||||
protocol = UPP(data.test, repeats=n_bags_val)
|
||||
modsel = GridSearchQ(quantifier, param_grid, protocol, refit=False, n_jobs=-1, verbose=1, error=optim)
|
||||
is_semeval = dataset.startswith('semeval')
|
||||
|
||||
modsel.fit(data.training)
|
||||
print(f'best params {modsel.best_params_}')
|
||||
print(f'best score {modsel.best_score_}')
|
||||
pickle.dump(
|
||||
(modsel.best_params_, modsel.best_score_,),
|
||||
open(f'{local_result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
|
||||
if not is_semeval or not semeval_trained:
|
||||
|
||||
quantifier = modsel.best_model()
|
||||
param_grid, quantifier = new_method(method)
|
||||
|
||||
if is_semeval:
|
||||
semeval_trained = True
|
||||
|
||||
else:
|
||||
print(f'model selection for {dataset} already done; skipping')
|
||||
# model selection
|
||||
data = qp.datasets.fetch_twitter(dataset, min_df=3, pickle=True, for_model_selection=True)
|
||||
|
||||
data = qp.datasets.fetch_twitter(dataset, min_df=3, pickle=True, for_model_selection=False)
|
||||
quantifier.fit(data.training)
|
||||
protocol = UPP(data.test, repeats=n_bags_test)
|
||||
report = qp.evaluation.evaluation_report(quantifier, protocol, error_metrics=['mae', 'mrae', 'kld'], verbose=True)
|
||||
report.to_csv(f'{local_result_path}.dataframe')
|
||||
means = report.mean()
|
||||
csv.write(f'{method}\t{data.name}\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
|
||||
csv.flush()
|
||||
protocol = UPP(data.test, repeats=n_bags_val)
|
||||
modsel = GridSearchQ(quantifier, param_grid, protocol, refit=False, n_jobs=-1, verbose=1, error=optim)
|
||||
|
||||
show_results(global_result_path)
|
||||
modsel.fit(data.training)
|
||||
print(f'best params {modsel.best_params_}')
|
||||
print(f'best score {modsel.best_score_}')
|
||||
pickle.dump(
|
||||
(modsel.best_params_, modsel.best_score_,),
|
||||
open(f'{local_result_path}.hyper.pkl', 'wb'), pickle.HIGHEST_PROTOCOL)
|
||||
|
||||
quantifier = modsel.best_model()
|
||||
|
||||
if is_semeval:
|
||||
semeval_trained = True
|
||||
|
||||
else:
|
||||
print(f'model selection for {dataset} already done; skipping')
|
||||
|
||||
data = qp.datasets.fetch_twitter(dataset, min_df=3, pickle=True, for_model_selection=False)
|
||||
quantifier.fit(data.training)
|
||||
protocol = UPP(data.test, repeats=n_bags_test)
|
||||
report = qp.evaluation.evaluation_report(quantifier, protocol, error_metrics=['mae', 'mrae', 'kld'], verbose=True)
|
||||
report.to_csv(f'{local_result_path}.dataframe')
|
||||
means = report.mean()
|
||||
csv.write(f'{method}\t{data.name}\t{means["mae"]:.5f}\t{means["mrae"]:.5f}\t{means["kld"]:.5f}\n')
|
||||
csv.flush()
|
||||
|
||||
show_results(global_result_path)
|
||||
|
|
Loading…
Reference in New Issue