stress_at_work_analysis/exploration/ml_pipeline_classification_with_clustering.py

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# %% 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 scipy import stats

from sklearn.model_selection import LeaveOneGroupOut, cross_validate
from sklearn.impute import SimpleImputer

from sklearn.dummy import DummyClassifier
from sklearn import linear_model, svm, naive_bayes, neighbors, tree, ensemble
import xgboost as xg 

from sklearn.cluster import KMeans

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
from machine_learning.classification_models import ClassificationModels

# %% [markdown]
# # RAPIDS models

# %% [markdown]
# ## Set script's parameters
n_clusters = 4 # Number of clusters (could be regarded as a hyperparameter)
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/30min_all_target_inputs/input_JCQ_job_demand_mean.csv")
index_columns = ["local_segment", "local_segment_label", "local_segment_start_datetime", "local_segment_end_datetime"]

clust_col = model_input.set_index(index_columns).var().idxmax() # age is a col with the highest variance

model_input.columns[list(model_input.columns).index('age'):-1]

lime_cols = [col for col in model_input if col.startswith('limesurvey')]
lime_cols
lime_col = 'limesurvey_demand_control_ratio_quartile'
clust_col = lime_col

model_input[clust_col].describe()


# %% jupyter={"source_hidden": true}

# Filter-out outlier rows by clust_col 
#model_input = model_input[(np.abs(stats.zscore(model_input[clust_col])) < 3)]

uniq = model_input[[clust_col, 'pid']].drop_duplicates().reset_index(drop=True)
uniq = uniq.dropna()
plt.bar(uniq['pid'], uniq[clust_col])

# %% jupyter={"source_hidden": true}
# Get clusters by cluster col & and merge the clusters to main df
km = KMeans(n_clusters=n_clusters).fit_predict(uniq.set_index('pid'))
np.unique(km, return_counts=True)
uniq['cluster'] = km
uniq

model_input = model_input.merge(uniq[['pid', 'cluster']])   

# %% jupyter={"source_hidden": true}
model_input.set_index(index_columns, inplace=True)

# %% jupyter={"source_hidden": true}
# Create dict with classification ml models
cm = ClassificationModels()
cmodels = cm.get_cmodels()

# %% jupyter={"source_hidden": true}
for k in range(n_clusters):
    model_input_subset = model_input[model_input["cluster"] == k].copy()
    bins = [-10, -1, 1, 10] # bins for z-scored targets
    model_input_subset.loc[:, 'target'] = \
        pd.cut(model_input_subset.loc[:, 'target'], bins=bins, labels=['low', 'medium', 'high'], right=False) #['low', 'medium', 'high']
    model_input_subset['target'].value_counts()
    model_input_subset = model_input_subset[model_input_subset['target'] != "medium"]
    model_input_subset['target'] = model_input_subset['target'].astype(str).apply(lambda x: 0 if x == "low" else 1)

    model_input_subset['target'].value_counts()
    
    if cv_method_str == 'half_logo':
        model_input_subset['pid_index'] = model_input_subset.groupby('pid').cumcount()
        model_input_subset['pid_count'] = model_input_subset.groupby('pid')['pid'].transform('count')

        model_input_subset["pid_index"] = (model_input_subset['pid_index'] / model_input_subset['pid_count'] + 1).round()
        model_input_subset["pid_half"] = model_input_subset["pid"] + "_" +  model_input_subset["pid_index"].astype(int).astype(str)

        data_x, data_y, data_groups = model_input_subset.drop(["target", "pid", "pid_index", "pid_half"], axis=1), model_input_subset["target"], model_input_subset["pid_half"]
    else:
        data_x, data_y, data_groups = model_input_subset.drop(["target", "pid"], axis=1), model_input_subset["target"], model_input_subset["pid"]

    # Treat categorical features
    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)

    # Establish cv method
    cv_method = StratifiedKFold(n_splits=5, shuffle=True) # 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,
        )

    imputer = SimpleImputer(missing_values=np.nan, strategy='median')

    for model_title, model in cmodels.items():

        classifier = cross_validate(
            model['model'],
            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')
        )
        
        print("\n-------------------------------------\n")
        print("Current cluster:", k, end="\n")
        print("Current model:", model_title, end="\n")
        print("Acc", np.mean(classifier['test_accuracy']))
        print("Precision", np.mean(classifier['test_precision']))
        print("Recall", np.mean(classifier['test_recall']))
        print("F1", np.mean(classifier['test_f1']))
        print(f"Largest {n_sl} ACC:", np.sort(-np.partition(-classifier['test_accuracy'], n_sl)[:n_sl])[::-1])
        print(f"Smallest {n_sl} ACC:", np.sort(np.partition(classifier['test_accuracy'], n_sl)[:n_sl]))
        
        cmodels[model_title]['metrics'][0] += np.mean(classifier['test_accuracy'])
        cmodels[model_title]['metrics'][1] += np.mean(classifier['test_precision'])
        cmodels[model_title]['metrics'][2] += np.mean(classifier['test_recall'])
        cmodels[model_title]['metrics'][3] += np.mean(classifier['test_f1'])

# %% jupyter={"source_hidden": true}
# Get overall results
cm.get_total_models_scores(n_clusters=n_clusters)