Prepare classification presentation.

presentation/classification.py

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+# ---
+# jupyter:
+#   jupytext:
+#     formats: ipynb,py:percent
+#     text_representation:
+#       extension: .py
+#       format_name: percent
+#       format_version: '1.3'
+#       jupytext_version: 1.13.0
+#   kernelspec:
+#     display_name: straw2analysis
+#     language: python
+#     name: straw2analysis
+# ---
+
+# %% jupyter={"source_hidden": true}
+# %matplotlib inline
+import datetime
+import importlib
+import os
+import sys
+
+import numpy as np
+import matplotlib.pyplot as plt
+import pandas as pd
+import seaborn as sns
+
+from sklearn import linear_model, svm, naive_bayes, neighbors, tree, ensemble 
+from sklearn.model_selection import LeaveOneGroupOut, cross_validate
+from sklearn.dummy import DummyClassifier
+from sklearn.impute import SimpleImputer
+
+from lightgbm import LGBMClassifier
+import xgboost as xg
+from IPython.core.interactiveshell import InteractiveShell
+InteractiveShell.ast_node_interactivity = "all"
+
+nb_dir = os.path.split(os.getcwd())[0]
+if nb_dir not in sys.path:
+    sys.path.append(nb_dir)
+
+import machine_learning.labels
+import machine_learning.model
+
+# %% [markdown]
+# # RAPIDS models
+
+# %% [markdown]
+# ## Set script's parameters
+cv_method_str = 'logo' # logo, halflogo, 5kfold # Cross-validation method (could be regarded as a hyperparameter)
+n_sl = 1 # Number of largest/smallest accuracies (of particular CV) outputs
+
+# %% jupyter={"source_hidden": true}
+model_input = pd.read_csv("../data/stressfulness_event_nonstandardized/input_appraisal_stressfulness_event_mean.csv")
+
+# %% jupyter={"source_hidden": true}
+index_columns = ["local_segment", "local_segment_label", "local_segment_start_datetime", "local_segment_end_datetime"]
+model_input.set_index(index_columns, inplace=True)
+model_input['target'].value_counts()
+
+# %% jupyter={"source_hidden": true}
+# bins = [-10, -1, 1, 10] # bins for z-scored targets
+bins = [0, 1, 4] # bins for stressfulness (1-4) target
+model_input['target'], edges = pd.cut(model_input.target, bins=bins, labels=['low', 'high'], retbins=True, right=True) #['low', 'medium', 'high']
+model_input['target'].value_counts(), edges
+# model_input = model_input[model_input['target'] != "medium"]
+model_input['target'] = model_input['target'].astype(str).apply(lambda x: 0 if x == "low" else 1)
+
+model_input['target'].value_counts()
+
+if cv_method_str == 'halflogo':
+    model_input['pid_index'] = model_input.groupby('pid').cumcount()
+    model_input['pid_count'] = model_input.groupby('pid')['pid'].transform('count')
+
+    model_input["pid_index"] = (model_input['pid_index'] / model_input['pid_count'] + 1).round()
+    model_input["pid_half"] = model_input["pid"] + "_" +  model_input["pid_index"].astype(int).astype(str)
+
+    data_x, data_y, data_groups = model_input.drop(["target", "pid", "pid_index", "pid_half"], axis=1), model_input["target"], model_input["pid_half"]
+else:
+    data_x, data_y, data_groups = model_input.drop(["target", "pid"], axis=1), model_input["target"], model_input["pid"]
+
+
+# %% jupyter={"source_hidden": true}
+categorical_feature_colnames = ["gender", "startlanguage"]
+additional_categorical_features = [col for col in data_x.columns if "mostcommonactivity" in col or "homelabel" in col]
+categorical_feature_colnames += additional_categorical_features
+
+categorical_features = data_x[categorical_feature_colnames].copy()
+mode_categorical_features = categorical_features.mode().iloc[0]
+
+# fillna with mode
+categorical_features = categorical_features.fillna(mode_categorical_features)
+
+# one-hot encoding
+categorical_features = categorical_features.apply(lambda col: col.astype("category"))
+if not categorical_features.empty:
+    categorical_features = pd.get_dummies(categorical_features)
+
+numerical_features = data_x.drop(categorical_feature_colnames, axis=1)
+train_x = pd.concat([numerical_features, categorical_features], axis=1)
+train_x.dtypes
+
+# %% jupyter={"source_hidden": true}
+cv_method = None # Defaults to 5 k-folds in cross_validate method
+if cv_method_str == 'logo' or cv_method_str == 'half_logo':
+    cv_method = LeaveOneGroupOut()
+    cv_method.get_n_splits(
+        train_x,
+        data_y,
+        groups=data_groups,
+    )
+
+# %% jupyter={"source_hidden": true}
+imputer = SimpleImputer(missing_values=np.nan, strategy='median')
+
+# %% [markdown]
+# ### Baseline: Dummy Classifier (most frequent)
+dummy_class = DummyClassifier(strategy="most_frequent")
+
+# %% jupyter={"source_hidden": true}
+dummy_classifier = cross_validate(
+    dummy_class,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'average_precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(dummy_classifier['test_accuracy']))
+print("Precision", np.mean(dummy_classifier['test_average_precision']))
+print("Recall", np.mean(dummy_classifier['test_recall']))
+print("F1", np.mean(dummy_classifier['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-dummy_classifier['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(dummy_classifier['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Logistic Regression
+
+# %% jupyter={"source_hidden": true}
+logistic_regression = linear_model.LogisticRegression()
+
+# %% jupyter={"source_hidden": true}
+log_reg_scores = cross_validate(
+    logistic_regression,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(log_reg_scores['test_accuracy']))
+print("Precision", np.mean(log_reg_scores['test_precision']))
+print("Recall", np.mean(log_reg_scores['test_recall']))
+print("F1", np.mean(log_reg_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-log_reg_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(log_reg_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Support Vector Machine
+
+# %% jupyter={"source_hidden": true}
+svc = svm.SVC()
+
+# %% jupyter={"source_hidden": true}
+svc_scores = cross_validate(
+    svc,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(svc_scores['test_accuracy']))
+print("Precision", np.mean(svc_scores['test_precision']))
+print("Recall", np.mean(svc_scores['test_recall']))
+print("F1", np.mean(svc_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-svc_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(svc_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Gaussian Naive Bayes
+
+# %% jupyter={"source_hidden": true}
+gaussian_nb = naive_bayes.GaussianNB()
+
+# %% jupyter={"source_hidden": true}
+gaussian_nb_scores = cross_validate(
+    gaussian_nb,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(gaussian_nb_scores['test_accuracy']))
+print("Precision", np.mean(gaussian_nb_scores['test_precision']))
+print("Recall", np.mean(gaussian_nb_scores['test_recall']))
+print("F1", np.mean(gaussian_nb_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-gaussian_nb_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(gaussian_nb_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Stochastic Gradient Descent Classifier
+
+# %% jupyter={"source_hidden": true}
+sgdc = linear_model.SGDClassifier()
+
+# %% jupyter={"source_hidden": true}
+sgdc_scores = cross_validate(
+    sgdc,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(sgdc_scores['test_accuracy']))
+print("Precision", np.mean(sgdc_scores['test_precision']))
+print("Recall", np.mean(sgdc_scores['test_recall']))
+print("F1", np.mean(sgdc_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-sgdc_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(sgdc_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### K-nearest neighbors
+
+# %% jupyter={"source_hidden": true}
+knn = neighbors.KNeighborsClassifier()
+
+# %% jupyter={"source_hidden": true}
+knn_scores = cross_validate(
+    knn,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(knn_scores['test_accuracy']))
+print("Precision", np.mean(knn_scores['test_precision']))
+print("Recall", np.mean(knn_scores['test_recall']))
+print("F1", np.mean(knn_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-knn_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(knn_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Decision Tree
+
+# %% jupyter={"source_hidden": true}
+dtree = tree.DecisionTreeClassifier()
+
+# %% jupyter={"source_hidden": true}
+dtree_scores = cross_validate(
+    dtree,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(dtree_scores['test_accuracy']))
+print("Precision", np.mean(dtree_scores['test_precision']))
+print("Recall", np.mean(dtree_scores['test_recall']))
+print("F1", np.mean(dtree_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-dtree_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(dtree_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Random Forest Classifier
+
+# %% jupyter={"source_hidden": true}
+rfc = ensemble.RandomForestClassifier()
+
+# %% jupyter={"source_hidden": true}
+rfc_scores = cross_validate(
+    rfc,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(rfc_scores['test_accuracy']))
+print("Precision", np.mean(rfc_scores['test_precision']))
+print("Recall", np.mean(rfc_scores['test_recall']))
+print("F1", np.mean(rfc_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-rfc_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(rfc_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### Gradient Boosting Classifier
+
+# %% jupyter={"source_hidden": true}
+gbc = ensemble.GradientBoostingClassifier()
+
+# %% jupyter={"source_hidden": true}
+gbc_scores = cross_validate(
+    gbc,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(gbc_scores['test_accuracy']))
+print("Precision", np.mean(gbc_scores['test_precision']))
+print("Recall", np.mean(gbc_scores['test_recall']))
+print("F1", np.mean(gbc_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-gbc_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(gbc_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### LGBM Classifier
+
+# %% jupyter={"source_hidden": true}
+lgbm = LGBMClassifier()
+
+# %% jupyter={"source_hidden": true}
+lgbm_scores = cross_validate(
+    lgbm,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(lgbm_scores['test_accuracy']))
+print("Precision", np.mean(lgbm_scores['test_precision']))
+print("Recall", np.mean(lgbm_scores['test_recall']))
+print("F1", np.mean(lgbm_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-lgbm_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(lgbm_scores['test_accuracy'], n_sl)[:n_sl]))
+
+# %% [markdown]
+# ### XGBoost Classifier
+
+# %% jupyter={"source_hidden": true}
+xgb_classifier = xg.sklearn.XGBClassifier()
+
+# %% jupyter={"source_hidden": true}
+xgb_classifier_scores = cross_validate(
+    xgb_classifier,
+    X=imputer.fit_transform(train_x),
+    y=data_y,
+    groups=data_groups,
+    cv=cv_method,
+    n_jobs=-1,
+    error_score='raise',
+    scoring=('accuracy', 'precision', 'recall', 'f1')
+)
+# %% jupyter={"source_hidden": true}
+print("Acc", np.mean(xgb_classifier_scores['test_accuracy']))
+print("Precision", np.mean(xgb_classifier_scores['test_precision']))
+print("Recall", np.mean(xgb_classifier_scores['test_recall']))
+print("F1", np.mean(xgb_classifier_scores['test_f1']))
+print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-xgb_classifier_scores['test_accuracy'], n_sl)[:n_sl])[::-1])
+print(f"Smallest {n_sl} ACC:", np.sort(np.partition(xgb_classifier_scores['test_accuracy'], n_sl)[:n_sl]))