LSHTM_analysis/scripts/ml/ml_functions/GetMLData.py

#!/usr/bin/env python3
# -*- coding: utf-8 -*-
"""
Created on Sun Mar  6 13:41:54 2022

@author: tanu
"""

#https://stackoverflow.com/questions/51695322/compare-multiple-algorithms-with-sklearn-pipeline
import os, sys
import pandas as pd
import numpy as np
print(np.__version__)
print(pd.__version__)
import pprint as pp
from copy import deepcopy
from collections import Counter
from sklearn.impute import KNNImputer as KNN
from imblearn.over_sampling import RandomOverSampler
from imblearn.under_sampling import RandomUnderSampler
from imblearn.over_sampling import SMOTE
from sklearn.datasets import make_classification
from imblearn.combine import SMOTEENN
from imblearn.combine import SMOTETomek

from imblearn.over_sampling import SMOTENC
from imblearn.under_sampling import EditedNearestNeighbours
from imblearn.under_sampling import RepeatedEditedNearestNeighbours

from sklearn.metrics import make_scorer, confusion_matrix, accuracy_score, balanced_accuracy_score, precision_score, average_precision_score, recall_score
from sklearn.metrics import roc_auc_score, roc_curve, f1_score, matthews_corrcoef, jaccard_score, classification_report

from sklearn.model_selection import train_test_split, cross_validate, cross_val_score
from sklearn.model_selection import StratifiedKFold,RepeatedStratifiedKFold, RepeatedKFold

from sklearn.pipeline import Pipeline, make_pipeline
import argparse
import re


def getmldata(gene, drug
              , data_combined_model = False
              , use_or = False
              , omit_all_genomic_features = False
              , write_maskfile = False
              , write_outfile = False):

    #%% FOR LATER: Combine ED logo data
    #%% constructuing genomic feature group
    #========================
    # FG: Genomic features
    #========================
    X_gn_maf_Fnum =  ['maf']
    #X_gn_or_Fnum =  ['logorI', 'or_rawI', 'or_mychisq', 'or_logistic', 'or_fisher', 'pval_fisher']
    
    X_gn_linegae_Fnum  = ['lineage_proportion'
                          , 'dist_lineage_proportion'
                          #, 'lineage' # could be included as a category but it has L2;L4  formatting
                          , 'lineage_count_all'
                          , 'lineage_count_unique']
    
    # X_gn_Fcat = ['drtype_mode_labels'  # beware then you can't use it to predict [USED it for uq_v1, not v2]
    #                #, 'gene_name'] # will be required for the combined stuff
    #X_gn_Fcat = []
    
    if data_combined_model:
        X_geneF = ['gene_name']
    else:
        X_geneF = []

    if use_or:
        X_gn_or_Fnum =  ['logorI']
    else:
        X_gn_or_Fnum = []
    
    if omit_all_genomic_features:
        print('\nOmitting all genomic features (n):', len(X_gn_maf_Fnum) + len(X_gn_or_Fnum) + len(X_gn_linegae_Fnum) + len(X_geneF))
        X_genomicFN = []
        if use_or:
           sys.exit('\nError: omitting genomic feature and using odds ratio are mutually exclusive')
    else:
        X_genomicFN = X_gn_maf_Fnum + X_gn_or_Fnum + X_gn_linegae_Fnum + X_geneF
       
    #%%
    ###########################################################################

    homedir = os.path.expanduser("~")
    
    geneL_basic     = ['pnca']
    geneL_na        = ['gid']
    geneL_na_ppi2   = ['rpob']
    geneL_ppi2      = ['alr', 'embb', 'katg']
    
    #num_type = ['int64', 'float64']
    num_type = ['int16', 'int32', 'int64', 'float16', 'float32', 'float64']
    cat_type = ['object', 'bool']
    
    #==============
    # directories
    #==============
    datadir = homedir + '/git/Data/'
    indir   = datadir + drug + '/input/'
    outdir  = datadir + drug + '/output/'
    outdir_ml = outdir + 'ml/'
      
    #==========================
    # outfile for ML training:
    #==========================
    outFile_ml = outdir_ml + gene.lower() + '_training_data.csv'
   
    outFile_mask_ml = outdir_ml + gene.lower() + '_mask_check.csv'
    
    #=======
    # input
    #=======
    
    #---------
    # File 1
    #---------
    infile_ml1 = outdir + gene.lower() + '_merged_df3.csv' 
    #infile_ml2 = outdir + gene.lower() + '_merged_df2.csv'
    
    my_features_df = pd.read_csv(infile_ml1, index_col = 0) 
    my_features_df  = my_features_df .reset_index(drop = True)
    my_features_df.index
    
    my_features_df.dtypes
    mycols = my_features_df.columns
    
    #---------
    # File 2
    #---------
    infile_aaindex = outdir + 'aa_index/' + gene.lower() + '_aa.csv' 
    aaindex_df = pd.read_csv(infile_aaindex, index_col = 0) 
    aaindex_df.dtypes
    
    #-----------
    # check for non-numerical columns
    #-----------
    if any(aaindex_df.dtypes==object):
        print('\naaindex_df contains non-numerical data')
    
    aaindex_df_object = aaindex_df.select_dtypes(include = cat_type)
    print('\nTotal no. of non-numerial columns:', len(aaindex_df_object.columns))
    
    expected_aa_ncols = len(aaindex_df.columns) - len(aaindex_df_object.columns)
    
    #-----------
    # Extract numerical data only
    #-----------
    print('\nSelecting numerical data only')
    aaindex_df = aaindex_df.select_dtypes(include = num_type)
    
    #---------------------------
    # aaindex: sanity check 1
    #---------------------------
    if len(aaindex_df.columns) == expected_aa_ncols:
        print('\nPASS: successfully selected numerical columns only for aaindex_df')
    else:
        print('\nFAIL: Numbers mismatch'
              , '\nExpected ncols:', expected_aa_ncols
              , '\nGot:', len(aaindex_df.columns))    
        
    #---------------
    # check for NA
    #---------------
    print('\nNow checking for NA in the remaining aaindex_cols')
    c1 = aaindex_df.isna().sum()
    c2 = c1.sort_values(ascending=False)
    print('\nCounting aaindex_df cols with NA'
          , '\nncols with NA:', sum(c2>0), 'columns'
          , '\nDropping these...'
          , '\nOriginal ncols:', len(aaindex_df.columns)
          )
    aa_df = aaindex_df.dropna(axis=1)
    
    print('\nRevised df ncols:', len(aa_df.columns))
    
    c3 = aa_df.isna().sum()
    c4 = c3.sort_values(ascending=False)
    
    print('\nChecking NA in revised df...')
    
    if sum(c4>0):
        sys.exit('\nFAIL: aaindex_df still contains cols with NA, please check and drop these before proceeding...')
    else:
        print('\nPASS: cols with NA successfully dropped from aaindex_df'
              , '\nProceeding with combining aa_df with other features_df')
        
    #---------------------------
    # aaindex: sanity check 2
    #---------------------------
    expected_aa_ncols2 =  len(aaindex_df.columns) - sum(c2>0)  
    if len(aa_df.columns) == expected_aa_ncols2:
        print('\nPASS: ncols match'
              , '\nExpected ncols:', expected_aa_ncols2
              , '\nGot:', len(aa_df.columns))
    else:
        print('\nFAIL: Numbers mismatch'
              , '\nExpected ncols:', expected_aa_ncols2
              , '\nGot:', len(aa_df.columns))            
        
    # Important: need this to identify aaindex cols    
    aa_df_cols = aa_df.columns
    print('\nTotal no. of columns in clean aa_df:', len(aa_df_cols))
    
    ###############################################################################
    #%% Combining my_features_df and aaindex_df
    #===========================
    # Merge my_df + aaindex_df
    #===========================
    
    if aa_df.columns[aa_df.columns.isin(my_features_df.columns)] == my_features_df.columns[my_features_df.columns.isin(aa_df.columns)]:
        print('\nMerging on column: mutationinformation')   
    
    if len(my_features_df) == len(aa_df):
        expected_nrows = len(my_features_df)
        print('\nProceeding to merge, expected nrows in merged_df:', expected_nrows)
    else:
        sys.exit('\nNrows mismatch, cannot merge. Please check'
              , '\nnrows my_df:', len(my_features_df)
              , '\nnrows aa_df:', len(aa_df))
               
    #-----------------
    # Reset index: mutationinformation
    # Very important for merging
    #-----------------
    aa_df = aa_df.reset_index()
    
    expected_ncols = len(my_features_df.columns) + len(aa_df.columns) - 1 # for the no. of merging col
    
    #-----------------
    # Merge: my_features_df + aa_df
    #-----------------
    merged_df = pd.merge(my_features_df
                         , aa_df
                         , on = 'mutationinformation')
    
    #---------------------------
    # aaindex: sanity check 3
    #---------------------------
    if len(merged_df.columns) == expected_ncols:
        print('\nPASS: my_features_df and aa_df successfully combined'
              , '\nnrows:', len(merged_df)
              , '\nncols:', len(merged_df.columns))
    else:
        sys.exit('\nFAIL: could not combine my_features_df and aa_df'
                 , '\nCheck dims and merging cols!')
        
    #--------
    # Reassign so downstream code doesn't need to change
    #--------
    my_df = merged_df.copy()
    
    #%% Data: my_df
    # Check if non structural pos have crept in
    # IDEALLY remove from source! But for rpoB do it here
    # Drop NA where numerical cols have them
    if gene.lower() in geneL_na_ppi2:
        #D1148 get rid of
        na_index = my_df['mutationinformation'].index[my_df['mcsm_na_affinity'].apply(np.isnan)]
        my_df = my_df.drop(index=na_index)
    
    ###########################################################################
    #%% Add lineage calculation columns
    #FIXME: Check if this can be imported from config?
    total_mtblineage_uc = 8
    lineage_colnames = ['lineage_list_all', 'lineage_count_all', 'lineage_count_unique', 'lineage_list_unique', 'lineage_multimode']
    #bar = my_df[lineage_colnames]
    my_df['lineage_proportion']      = my_df['lineage_count_unique']/my_df['lineage_count_all']
    my_df['dist_lineage_proportion'] = my_df['lineage_count_unique']/total_mtblineage_uc
    ###########################################################################
    #%% Active site annotation column
    # change from numberic to categorical
    
    if my_df['active_site'].dtype in num_type:
        my_df['active_site'] = my_df['active_site'].astype(object)
        my_df['active_site'].dtype
    #%% AA property change
    #--------------------
    # Water prop change
    #--------------------
    my_df['water_change'] = my_df['wt_prop_water'] + str('_to_') + my_df['mut_prop_water']
    my_df['water_change'].value_counts()
    
    water_prop_changeD = {
        'hydrophobic_to_neutral'          : 'change'
        , 'hydrophobic_to_hydrophobic'    : 'no_change'
        , 'neutral_to_neutral'            : 'no_change'
        , 'neutral_to_hydrophobic'        : 'change'
        , 'hydrophobic_to_hydrophilic'    : 'change'
        , 'neutral_to_hydrophilic'        : 'change'
        , 'hydrophilic_to_neutral'        : 'change'
        , 'hydrophilic_to_hydrophobic'    : 'change'
        , 'hydrophilic_to_hydrophilic'    : 'no_change'
    }
    
    my_df['water_change'] = my_df['water_change'].map(water_prop_changeD)
    my_df['water_change'].value_counts()
    
    #--------------------
    # Polarity change
    #--------------------
    my_df['polarity_change'] = my_df['wt_prop_polarity'] + str('_to_') + my_df['mut_prop_polarity']
    my_df['polarity_change'].value_counts()
    
    polarity_prop_changeD = {
        'non-polar_to_non-polar'     : 'no_change'
        , 'non-polar_to_neutral'     : 'change'  
        , 'neutral_to_non-polar'     : 'change'  
        , 'neutral_to_neutral'       : 'no_change'  
        , 'non-polar_to_basic'       : 'change'  
        , 'acidic_to_neutral'        : 'change'  
        , 'basic_to_neutral'         : 'change'  
        , 'non-polar_to_acidic'      : 'change'  
        , 'neutral_to_basic'         : 'change'  
        , 'acidic_to_non-polar'      : 'change'  
        , 'basic_to_non-polar'       : 'change'
        , 'neutral_to_acidic'        : 'change'
        , 'acidic_to_acidic'         : 'no_change'
        , 'basic_to_acidic'          : 'change'
        , 'basic_to_basic'           : 'no_change'
        , 'acidic_to_basic'          : 'change'}
    
    my_df['polarity_change'] = my_df['polarity_change'].map(polarity_prop_changeD)
    my_df['polarity_change'].value_counts()
    
    #--------------------
    # Electrostatics change
    #--------------------
    my_df['electrostatics_change'] = my_df['wt_calcprop'] + str('_to_') + my_df['mut_calcprop']
    my_df['electrostatics_change'].value_counts()
    
    calc_prop_changeD = {
            'non-polar_to_non-polar'     : 'no_change'
            , 'non-polar_to_polar'       : 'change'
            , 'polar_to_non-polar'       : 'change'
            , 'non-polar_to_pos'         : 'change'
            , 'neg_to_non-polar'         : 'change'
            , 'non-polar_to_neg'         : 'change'
            , 'pos_to_polar'             : 'change'
            , 'pos_to_non-polar'         : 'change'
            , 'polar_to_polar'           : 'no_change'
            , 'neg_to_neg'               : 'no_change'
            , 'polar_to_neg'             : 'change'
            , 'pos_to_neg'               : 'change'
            , 'pos_to_pos'               : 'no_change'
            , 'polar_to_pos'             : 'change'
            , 'neg_to_polar'             : 'change'
            , 'neg_to_pos'               : 'change'
    }
    
    my_df['electrostatics_change'] = my_df['electrostatics_change'].map(calc_prop_changeD)
    my_df['electrostatics_change'].value_counts()
    
    #--------------------    
    # Summary change: Create a combined column summarising these three cols
    #--------------------
    detect_change = 'change'
    check_prop_cols = ['water_change', 'polarity_change', 'electrostatics_change']
    #my_df['aa_prop_change'] = (my_df.values == detect_change).any(1).astype(int)
    my_df['aa_prop_change'] = (my_df[check_prop_cols].values == detect_change).any(1).astype(int)
    my_df['aa_prop_change'].value_counts()
    my_df['aa_prop_change'].dtype
    
    my_df['aa_prop_change'] = my_df['aa_prop_change'].map({1:'change'
                                                           , 0: 'no_change'})
    
    my_df['aa_prop_change'].value_counts()
    my_df['aa_prop_change'].dtype
    
    #%% IMPUTE values for OR [check script for exploration: UQ_or_imputer]
    #--------------------
    # Impute OR values
    #--------------------
    #or_cols = ['or_mychisq', 'log10_or_mychisq', 'or_fisher']
    sel_cols = ['mutationinformation', 'or_mychisq', 'log10_or_mychisq']
    or_cols = ['or_mychisq', 'log10_or_mychisq']
    
    print("count of NULL values before imputation\n")
    print(my_df[or_cols].isnull().sum())
    
    my_dfI = pd.DataFrame(index = my_df['mutationinformation'] )
    
        
    my_dfI = pd.DataFrame(KNN(n_neighbors=3, weights="uniform").fit_transform(my_df[or_cols])
                          , index =  my_df['mutationinformation']
                          , columns = or_cols )
    my_dfI.columns = ['or_rawI', 'logorI']
    my_dfI.columns
    my_dfI = my_dfI.reset_index(drop = False) # prevents old index from being added as a column
    my_dfI.head()
    print("count of NULL values AFTER imputation\n")
    print(my_dfI.isnull().sum())
    
    #-------------------------------------------
    # OR df Merge: with original based on index
    #-------------------------------------------
    #my_df['index_bm'] = my_df.index
    mydf_imputed = pd.merge(my_df
                        , my_dfI
                        , on = 'mutationinformation')
    #mydf_imputed = mydf_imputed.set_index(['index_bm'])
    
    my_df['log10_or_mychisq'].isna().sum()
    mydf_imputed['log10_or_mychisq'].isna().sum()
    mydf_imputed['logorI'].isna().sum() # should be 0
    
    len(my_df.columns)
    len(mydf_imputed.columns)  
    
    #-----------------------------------------
    # REASSIGN my_df after imputing OR values
    #-----------------------------------------
    my_df = mydf_imputed.copy()
    
    if my_df['logorI'].isna().sum() == 0:
        print('\nPASS: OR values imputed, data ready for ML')
    else:
        sys.exit('\nFAIL: something went wrong, Data not ready for ML. Please check upstream!')
    
    #!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
    #---------------------------------------
    # TODO: try other imputation like MICE
    #---------------------------------------
    #!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
    
    #%%########################################################################
    #==========================
    #     Data for ML
    #==========================
    my_df_ml = my_df.copy()
    
    # Build column names to mask for affinity chanhes
    if gene.lower() in geneL_basic:
        #X_stabilityN = common_cols_stabiltyN
        gene_affinity_colnames = []# not needed as its the common ones 
        cols_to_mask = ['ligand_affinity_change']
        
    if gene.lower() in geneL_ppi2:
        gene_affinity_colnames = ['mcsm_ppi2_affinity', 'interface_dist'] 
        #X_stabilityN = common_cols_stabiltyN + geneL_ppi2_st_cols
        cols_to_mask = ['ligand_affinity_change', 'mcsm_ppi2_affinity']
    
    if gene.lower() in geneL_na:
        gene_affinity_colnames =  ['mcsm_na_affinity'] 
        #X_stabilityN = common_cols_stabiltyN + geneL_na_st_cols
        cols_to_mask = ['ligand_affinity_change', 'mcsm_na_affinity']
    
    if gene.lower() in geneL_na_ppi2:
        gene_affinity_colnames = ['mcsm_na_affinity'] + ['mcsm_ppi2_affinity', 'interface_dist'] 
        #X_stabilityN = common_cols_stabiltyN + geneL_na_ppi2_st_cols
        cols_to_mask = ['ligand_affinity_change', 'mcsm_na_affinity', 'mcsm_ppi2_affinity']
    
    #=======================
    # Masking columns:
    # (mCSM-lig, mCSM-NA, mCSM-ppi2) values for lig_dist >10
    #=======================
    my_df_ml['mutationinformation'][my_df_ml['ligand_distance']>10].value_counts()
    my_df_ml.groupby('mutationinformation')['ligand_distance'].apply(lambda x: (x>10)).value_counts()
    my_df_ml.loc[(my_df_ml['ligand_distance'] > 10), cols_to_mask].value_counts()
    
    # mask the mcsm affinity related columns where ligand distance > 10
    my_df_ml.loc[(my_df_ml['ligand_distance'] > 10), cols_to_mask] = 0
    (my_df_ml['ligand_affinity_change'] == 0).sum()
    
    mask_check = my_df_ml[['mutationinformation', 'ligand_distance'] + cols_to_mask]  
    
    #===================================================
    # write file for check
    #mask_check.sort_values(by = ['ligand_distance'], ascending = True, inplace = True)
    #mask_check.to_csv(outdir + 'ml/' + gene.lower() + '_mask_check.csv')
    #===================================================
    ###############################################################################
    #%% Feature groups (FG): Build X for Input ML 
    ############################################################################
    #===========================
    # FG1: Evolutionary features
    #===========================
    X_evolFN =  ['consurf_score'
               , 'snap2_score'
               , 'provean_score']
    
    ###############################################################################
    #========================
    # FG2: Stability features
    #========================
    #--------
    # common
    #--------
    X_common_stability_Fnum = [
               'duet_stability_change'
               , 'ddg_foldx'
               , 'deepddg'
               , 'ddg_dynamut2'
               , 'contacts']
    #--------
    # FoldX
    #--------
    X_foldX_Fnum = [ 'electro_rr', 'electro_mm', 'electro_sm', 'electro_ss'
    , 'disulfide_rr', 'disulfide_mm', 'disulfide_sm', 'disulfide_ss'
    , 'hbonds_rr', 'hbonds_mm', 'hbonds_sm', 'hbonds_ss'
    , 'partcov_rr', 'partcov_mm', 'partcov_sm', 'partcov_ss'
    , 'vdwclashes_rr', 'vdwclashes_mm', 'vdwclashes_sm', 'vdwclashes_ss'
    , 'volumetric_rr', 'volumetric_mm', 'volumetric_ss']
    
    X_stability_FN = X_common_stability_Fnum + X_foldX_Fnum
    
    ###############################################################################
    #===================
    # FG3: Affinity features
    #===================
    common_affinity_Fnum =  ['ligand_distance'
                    , 'ligand_affinity_change'
                    , 'mmcsm_lig']
    
    # if gene.lower() in geneL_basic:
    #     X_affinityFN = common_affinity_Fnum 
    # else:
    #     X_affinityFN = common_affinity_Fnum + gene_affinity_colnames
        
    X_affinityFN = common_affinity_Fnum + gene_affinity_colnames
    
    ###############################################################################
    #============================
    # FG4: Residue level features
    #============================
    #-----------
    # AA index
    #-----------
    X_aaindex_Fnum = list(aa_df_cols)
    print('\nTotal no. of features for aaindex:', len(X_aaindex_Fnum))
    
    #-----------------
    # surface area
    # depth
    # hydrophobicity
    #-----------------
    X_str_Fnum =  ['rsa'
               #, 'asa'
               , 'kd_values'
               , 'rd_values']   
    
    #---------------------------
    # Other aa properties
    # active site indication
    #---------------------------
    X_aap_Fcat = ['ss_class'
                # , 'wt_prop_water'
                # , 'mut_prop_water'
                # , 'wt_prop_polarity'
                # , 'mut_prop_polarity'
                # , 'wt_calcprop'
                # , 'mut_calcprop'
                , 'aa_prop_change'
                , 'electrostatics_change'
                , 'polarity_change'
                , 'water_change'
                , 'active_site']
       
    X_resprop_FN = X_aaindex_Fnum + X_str_Fnum + X_aap_Fcat
    ###############################################################################
    #========================
    # FG5: Genomic features
    #========================
    # See the beginnning section
    if use_or:
        print('\nALL Genomic features being used (n):', len(X_genomicFN)
          , '\nThese are:', X_genomicFN)
    else:
        print('\nGenomic features being used EXCLUDING odds ratio (n):', len(X_genomicFN)
          , '\nThese are:', X_genomicFN)
   
    ###############################################################################
    #========================
    # FG6 collapsed: Structural : Atability + Affinity + ResidueProp
    #========================
    X_structural_FN =  X_stability_FN + X_affinityFN + X_resprop_FN
    
    ###############################################################################
    #========================
    # BUILDING all features
    #========================
    all_featuresN = X_evolFN + X_structural_FN + X_genomicFN
    
    ###############################################################################
    #%% Define training and test data
    #================================================================
    # Training and BLIND test set: 70/30
    # dst with actual values  : training set
    # dst with imputed values : THROW AWAY [unrepresentative]
    #================================================================
    my_df_ml[drug].isna().sum()
    
    #    blind_test_df = my_df_ml[my_df_ml[drug].isna()]
    #    blind_test_df.shape
    
    # training_df = my_df_ml[my_df_ml[drug].notna()]
    # training_df.shape
    
    # training_df = my_df_ml.copy()
     
    # # Target 1: dst_mode
    # training_df[drug].value_counts()
    # training_df['dst_mode'].value_counts()
    
    #all_training_df = my_df_ml[all_featuresN]

    # Getting the dst column as this will be required for tts_split()    
    if 'dst' in my_df_ml:
        print('\ndst column exists')
        if my_df_ml['dst'].equals(my_df_ml[drug]):
            print('\nand this is identical to drug column:', drug)
    
        all_featuresN2 = all_featuresN + ['dst', 'dst_mode']
        all_training_df = my_df_ml[all_featuresN2]
        
    print('\nAll feature names:', all_featuresN2)
    ####################################################################

    #==========================================================================
    if write_maskfile:
        print('\nPASS: and now writing file to check masked columns and values:', outFile_mask_ml )
        mask_check.sort_values(by = ['ligand_distance'], ascending = True, inplace = True)
        mask_check.to_csv(outFile_mask_ml, index = False)
    else:
        print('\nPASS: but NOT writing mask file')
    #==========================================================================
    if write_outfile:
        print('\nPASS: and now writing processed file for ml:', outFile_ml)
        #all_training_df.to_csv(outFile_ml, index = False)
    else:
        print('\nPASS: But NOT writing processed file')
    #==========================================================================
    
    print('\n#################################################################'
          , '\nSUCCESS: Extacted training data for gene:', gene.lower()
          , '\nDim of training_df:', all_training_df.shape)
    if use_or:
        print('\nThis includes Odds Ratio'
              , '\n###########################################################')
    else:
        print('\nThis EXCLUDES Odds Ratio'
              , '\n############################################################')
 
    return(all_training_df)