コード例 #1
0
ファイル: CVTestCaseB.py プロジェクト: Zeigar/photon
    def testCaseB(self):
        pca_n_components = [7, 15, 10]
        svc_c = [.1, 1]
        #svc_kernel = ['rbf']
        svc_kernel = ['rbf', 'linear']
        cv_outer = ShuffleSplit(n_splits=1, test_size=0.2, random_state=3)
        cv_inner_1 = ShuffleSplit(n_splits=1, test_size=0.2, random_state=3)
        cv_inner_2 = ShuffleSplit(n_splits=1, test_size=0.2, random_state=3)

        # SET UP HYPERPIPE
        outer_pipe = Hyperpipe('outer_pipe',
                               optimizer='grid_search',
                               metrics=['accuracy'],
                               inner_cv=cv_inner_1,
                               outer_cv=cv_outer,
                               eval_final_performance=True)
        inner_pipe = Hyperpipe('pca_pipe',
                               optimizer='grid_search',
                               inner_cv=cv_inner_2,
                               eval_final_performance=False)

        inner_pipe.add(PipelineElement.create('standard_scaler'))
        inner_pipe.add(
            PipelineElement.create('ae_pca',
                                   {'n_components': pca_n_components}))

        pipeline_fusion = PipelineStacking('fusion_element', [inner_pipe])

        outer_pipe.add(pipeline_fusion)
        outer_pipe.add(
            PipelineElement.create('svc', {
                'C': svc_c,
                'kernel': svc_kernel
            }))

        # START HYPERPARAMETER SEARCH
        outer_pipe.fit(self.__X, self.__y)
        print(outer_pipe._test_performances)
        pipe_results = {'train': [], 'test': []}
        for i in range(len(outer_pipe._performance_history_list)):
            pipe_results['train'].extend(
                outer_pipe._performance_history_list[i]['accuracy_folds']
                ['train'])
            pipe_results['test'].extend(outer_pipe._performance_history_list[i]
                                        ['accuracy_folds']['test'])

        print(outer_pipe._test_performances['accuracy'])

        print('\n\n')
        print('Running sklearn version...\n')
        opt_tr_acc = []
        opt_test_acc = []

        for train_1, test in cv_outer.split(self.__X):
            data_train_1 = self.__X[train_1]
            data_test = self.__X[test]
            y_train_1 = self.__y[train_1]
            y_test = self.__y[test]
            config_inner_1 = {'C': [], 'kernel': []}
            sk_results_inner1 = {
                'train_2': [],
                'val_1': [],
                'train_2_mean': [],
                'val_1_mean': []
            }
            print('Outer Split')
            print('n train_1:', data_train_1.shape[0], '\n')

            for c in svc_c:
                for current_kernel in svc_kernel:
                    config_inner_1['C'].extend([c])
                    config_inner_1['kernel'].extend([current_kernel])

                    print('C:', c, 'Kernel:', current_kernel, '\n')
                    svc_score_tr = []
                    svc_score_te = []
                    fold_cnt = 1
                    for train_2, val_1 in cv_inner_1.split(data_train_1):
                        print('\n\nSklearn Outer Pipe FoldMetrics', fold_cnt)

                        data_train_2 = data_train_1[train_2]
                        data_val_1 = data_train_1[val_1]
                        y_train_2 = y_train_1[train_2]
                        y_val_1 = y_train_1[val_1]
                        print('n train_2:', data_train_2.shape[0], '\n')

                        config_inner_2 = {'n_comp': []}
                        print('Sklearn PCA Pipe')
                        sk_results_inner2 = {
                            'train_3': [],
                            'val_2': [],
                            'train_3_mean': [],
                            'val_2_mean': []
                        }
                        for n_comp in pca_n_components:
                            config_inner_2['n_comp'].extend([n_comp])

                            tr_acc = []
                            val_acc = []

                            # print('Some training data:',
                            #       data_train_2[0:2, 0:2])
                            for train_3, val_2 in cv_inner_2.split(
                                    data_train_2):

                                data_train_3 = data_train_2[train_3]
                                data_val_2 = data_train_2[val_2]

                                my_scaler = StandardScaler()
                                my_scaler.fit(data_train_3)
                                data_train_3 = my_scaler.transform(
                                    data_train_3)
                                data_val_2 = my_scaler.transform(data_val_2)

                                # Run PCA
                                my_pca = PCA_AE_Wrapper(n_components=n_comp)
                                my_pca.fit(data_train_3)

                                mae_tr = my_pca.score(data_train_3)
                                mae_te = my_pca.score(data_val_2)

                                tr_acc.append(mae_tr)
                                val_acc.append(mae_te)

                            sk_results_inner2['train_3'].extend(tr_acc)
                            sk_results_inner2['val_2'].extend(val_acc)
                            sk_results_inner2['train_3_mean'].extend(
                                [np.mean(tr_acc)])
                            sk_results_inner2['val_2_mean'].extend(
                                [np.mean(val_acc)])

                            print('n_comp:', n_comp)
                            print('n train_3 fold 1:', data_train_3.shape[0])
                            print('Training 3 mean:', [np.mean(tr_acc)],
                                  'validation 2 mean:', [np.mean(val_acc)])
                        # find best config for val 2
                        best_config_id = np.argmin(
                            sk_results_inner2['val_2_mean'])
                        print('Best PCA config:',
                              config_inner_2['n_comp'][best_config_id], '\n')
                        # fit optimum pipe

                        my_scaler = StandardScaler()
                        my_scaler.fit(data_train_2)
                        data_train_2 = my_scaler.transform(data_train_2)
                        data_val_1 = my_scaler.transform(data_val_1)

                        # Run PCA
                        my_pca = PCA_AE_Wrapper(
                            n_components=config_inner_2['n_comp']
                            [best_config_id])
                        my_pca.fit(data_train_2)
                        data_tr_2_pca = my_pca.transform(data_train_2)
                        data_val_1_pca = my_pca.transform(data_val_1)

                        # Run SVC
                        my_svc = SVC(kernel=current_kernel, C=c)
                        my_svc.fit(data_tr_2_pca, y_train_2)
                        svc_score_tr.append(
                            my_svc.score(data_tr_2_pca, y_train_2))
                        svc_score_te.append(
                            my_svc.score(data_val_1_pca, y_val_1))
                        print('Fit Optimum PCA Config and train with SVC')
                        print('n train 2:', data_train_2.shape[0])
                        print('n_comp:',
                              config_inner_2['n_comp'][best_config_id])
                        print('SVC Train:', svc_score_tr[-1])
                        print('SVC test:', svc_score_te[-1], '\n\n')
                        sk_results_inner1['train_2'].append(svc_score_tr[-1])
                        sk_results_inner1['val_1'].append(svc_score_te[-1])
                        fold_cnt += 1
                    sk_results_inner1['train_2_mean'].append(
                        np.mean(svc_score_tr))
                    sk_results_inner1['val_1_mean'].append(
                        np.mean(svc_score_te))

            print('\nNow find best config for SVC...')
            best_config_id_inner_1 = np.argmax(sk_results_inner1['val_1_mean'])
            print('Some test data:')
            print(data_test.shape)
            print(data_test[0:2, 0:2])

            # fit optimum pipe
            my_scaler = StandardScaler()
            my_scaler.fit(data_train_1)
            data_train_1 = my_scaler.transform(data_train_1)
            data_test = my_scaler.transform(data_test)

            # Run PCA
            my_pca = PCA_AE_Wrapper(
                n_components=config_inner_2['n_comp'][best_config_id])
            my_pca.fit(data_train_1)
            data_tr_1_pca = my_pca.transform(data_train_1)
            data_test_pca = my_pca.transform(data_test)

            # Run SVC
            my_svc = SVC(
                kernel=config_inner_1['kernel'][best_config_id_inner_1],
                C=config_inner_1['C'][best_config_id_inner_1])
            print('Best overall config:...')
            print('C = ', config_inner_1['C'][best_config_id_inner_1])
            print('kernel=', config_inner_1['kernel'][best_config_id_inner_1])
            print('pca_n_comp=', config_inner_2['n_comp'][best_config_id])
            print('n train 1:', data_train_1.shape[0])
            my_svc.fit(data_tr_1_pca, y_train_1)

            opt_tr_acc.append(my_svc.score(data_tr_1_pca, y_train_1))
            opt_test_acc.append(my_svc.score(data_test_pca, y_test))
            print('Train Acc:', opt_tr_acc[-1])
            print('test Acc:', opt_test_acc[-1])

        print('\nCompare results of last iteration (outer cv)...')
        print('SkL  Train:', sk_results_inner1['train_2'])
        print('Pipe Train:', pipe_results['train'])
        print('SkL  test: ', sk_results_inner1['val_1'])
        print('Pipe test: ', pipe_results['test'])
        print('\nEval final performance:')
        print('Pipe final perf:', outer_pipe._test_performances['accuracy'])
        print('Sklearn final perf:', opt_test_acc)
        self.assertEqual(sk_results_inner1['train_2'], pipe_results['train'])
        self.assertEqual(sk_results_inner1['val_1'], pipe_results['test'])
        self.assertEqual(opt_test_acc,
                         outer_pipe._test_performances['accuracy'])
コード例 #2
0
ファイル: PipelineElementTests.py プロジェクト: Zeigar/photon
class HyperpipeTests(unittest.TestCase):
    def setUp(self):
        self.pca_pipe_element = PipelineElement.create(
            'pca', {'n_components': [1, 2]}, test_disabled=True)
        self.svc_pipe_element = PipelineElement.create('svc', {
            'C': [0.1, 1],
            'kernel': ['rbf', 'sigmoid']
        })
        self.cv_object = KFold(n_splits=3)
        self.hyperpipe = Hyperpipe('god', self.cv_object)
        self.hyperpipe += self.pca_pipe_element
        self.hyperpipe.add(self.svc_pipe_element)

    def test_init(self):
        self.assertEqual(self.hyperpipe.name, 'god')
        # assure pipeline has two steps, first the pca and second the svc
        self.assertEqual(len(self.hyperpipe._pipe.steps), 2)
        self.assertIs(self.hyperpipe._pipe.steps[0][1], self.pca_pipe_element)
        self.assertIs(self.hyperpipe._pipe.steps[1][1], self.svc_pipe_element)

    def test_hyperparameters(self):
        # hyperparameters
        self.assertDictEqual(
            self.hyperpipe.hyperparameters, {
                'pca': {
                    'n_components': [1, 2],
                    'test_disabled': True
                },
                'svc': {
                    'C': [0.1, 1],
                    'kernel': ['rbf', 'sigmoid']
                }
            })
        # sklearn params
        # Todo: has no sklearn attribute
        # config grid
        # print(self.hyperpipe.config_grid)
        expected_config_grid = [{
            'pca__n_components': 1,
            'pca__disabled': False,
            'svc__C': 0.1,
            'svc__kernel': 'rbf'
        }, {
            'pca__n_components': 1,
            'pca__disabled': False,
            'svc__C': 0.1,
            'svc__kernel': 'sigmoid'
        }, {
            'pca__n_components': 1,
            'pca__disabled': False,
            'svc__C': 1,
            'svc__kernel': 'rbf'
        }, {
            'pca__n_components': 1,
            'pca__disabled': False,
            'svc__C': 1,
            'svc__kernel': 'sigmoid'
        }, {
            'pca__n_components': 2,
            'pca__disabled': False,
            'svc__C': 0.1,
            'svc__kernel': 'rbf'
        }, {
            'pca__n_components': 2,
            'pca__disabled': False,
            'svc__C': 0.1,
            'svc__kernel': 'sigmoid'
        }, {
            'pca__n_components': 2,
            'pca__disabled': False,
            'svc__C': 1,
            'svc__kernel': 'rbf'
        }, {
            'pca__n_components': 2,
            'pca__disabled': False,
            'svc__C': 1,
            'svc__kernel': 'sigmoid'
        }, {
            'pca__disabled': True,
            'svc__C': 0.1,
            'svc__kernel': 'rbf'
        }, {
            'pca__disabled': True,
            'svc__C': 0.1,
            'svc__kernel': 'sigmoid'
        }, {
            'pca__disabled': True,
            'svc__C': 1,
            'svc__kernel': 'rbf'
        }, {
            'pca__disabled': True,
            'svc__C': 1,
            'svc__kernel': 'sigmoid'
        }]
        expected_config_grid = [sorted(i) for i in expected_config_grid]
        actual_config_grid = [sorted(i) for i in self.hyperpipe.config_grid]
        self.assertListEqual(actual_config_grid, expected_config_grid)
コード例 #3
0
    def testCaseC2(self):
        pca_n_components = [5, 10]
        svc_c = [0.1]
        svc_c_2 = [1]
        #svc_kernel = ['rbf']
        svc_kernel = ['linear']

        # SET UP HYPERPIPE

        outer_pipe = Hyperpipe('outer_pipe',
                               optimizer='grid_search',
                               metrics=['accuracy'],
                               inner_cv=ShuffleSplit(n_splits=1,
                                                     test_size=0.2,
                                                     random_state=3),
                               outer_cv=ShuffleSplit(n_splits=1,
                                                     test_size=0.2,
                                                     random_state=3),
                               eval_final_performance=True)

        # Create pipe for first data source
        pipe_source_1 = Hyperpipe('source_1',
                                  optimizer='grid_search',
                                  inner_cv=ShuffleSplit(n_splits=1,
                                                        test_size=0.2,
                                                        random_state=3),
                                  eval_final_performance=False)

        pipe_source_1.add(
            PipelineElement.create('SourceSplitter',
                                   {'column_indices': [np.arange(0, 10)]}))
        pipe_source_1.add(
            PipelineElement.create('pca', {'n_components': pca_n_components}))
        pipe_source_1.add(
            PipelineElement.create('svc', {
                'C': svc_c,
                'kernel': svc_kernel
            }))

        # Create pipe for second data source
        pipe_source_2 = Hyperpipe('source_2',
                                  optimizer='grid_search',
                                  inner_cv=ShuffleSplit(n_splits=1,
                                                        test_size=0.2,
                                                        random_state=3),
                                  eval_final_performance=False)

        pipe_source_2.add(
            PipelineElement.create('SourceSplitter',
                                   {'column_indices': [np.arange(10, 20)]}))

        pipe_source_2.add(
            PipelineElement.create('pca', {'n_components': pca_n_components}))
        pipe_source_2.add(
            PipelineElement.create('svc', {
                'C': svc_c,
                'kernel': svc_kernel
            }))
        # Create pipe for third data source
        pipe_source_3 = Hyperpipe('source_3',
                                  optimizer='grid_search',
                                  inner_cv=ShuffleSplit(n_splits=1,
                                                        test_size=0.2,
                                                        random_state=3),
                                  eval_final_performance=False)

        pipe_source_3.add(
            PipelineElement.create('SourceSplitter',
                                   {'column_indices': [np.arange(20, 30)]}))
        pipe_source_3.add(
            PipelineElement.create('pca', {'n_components': pca_n_components}))
        pipe_source_3.add(
            PipelineElement.create('svc', {
                'C': svc_c,
                'kernel': svc_kernel
            }))

        # pipeline_fusion = PipelineStacking('multiple_source_pipes',[pipe_source_1, pipe_source_2, pipe_source_3], voting=False)
        pipeline_fusion = PipelineStacking(
            'multiple_source_pipes',
            [pipe_source_1, pipe_source_2, pipe_source_3])

        outer_pipe.add(pipeline_fusion)
        #outer_pipe.add(PipelineElement.create('svc', {'C': svc_c_2, 'kernel': svc_kernel}))
        #outer_pipe.add(PipelineElement.create('knn',{'n_neighbors':[15]}))
        outer_pipe.add(
            PipelineElement.create('kdnn', {
                'target_dimension': [2],
                'nb_epoch': [10]
            }))

        # START HYPERPARAMETER SEARCH
        outer_pipe.fit(self.__X, self.__y)
        print(outer_pipe._test_performances)
        pipe_results = {'train': [], 'test': []}
        for i in range(int(len(outer_pipe._performance_history_list) / 2)):
            pipe_results['train'].extend(
                outer_pipe._performance_history_list[i]['accuracy_folds']
                ['train'])
            pipe_results['test'].extend(outer_pipe._performance_history_list[i]
                                        ['accuracy_folds']['test'])

        print(outer_pipe._test_performances['accuracy'])
コード例 #4
0
ファイル: MongoDBTree.py プロジェクト: Zeigar/photon
print(np.sum(y)/len(y))

from pymodm import connect
connect("mongodb://localhost:27017/photon_db")

# BUILD PIPELINE
manager = Hyperpipe('test_manager',
                    optimizer='timeboxed_random_grid_search', optimizer_params={'limit_in_minutes': 1},
                    outer_cv=ShuffleSplit(test_size=0.2, n_splits=3),
                    inner_cv=KFold(n_splits=10, shuffle=True), best_config_metric='accuracy',
                    metrics=['accuracy', 'precision', 'recall', "f1_score"],
                    logging=False, eval_final_performance=True,
                    calculate_metrics_across_folds=True,
                    verbose=2)

manager.add(PipelineElement.create('standard_scaler', test_disabled=True))
manager += PipelineElement.create('pca', hyperparameters={'n_components': [None, 1, 10000]})
# tmp_lasso = Lasso()
# manager.add(PipelineElement.create('SelectModelWrapper', estimator_obj=tmp_lasso))

svm = PipelineElement.create('svc', hyperparameters={'C': [0.5, 1], 'kernel': ['linear']})
manager.add(svm)
manager.fit(X, y)

#  -----------> Result Tree generated ------------------- #
result_tree = manager.result_tree
# result_tree.write_to_db()

# THE END
debugging = True