I have a dataset of ~2m observations which I need to split into training, validation and test sets in the ratio 60:20:20. A simplified excerpt of my dataset looks like this:

| note_id | subject_id | category  |   note    |
|       1 |          1 | ECG       | blah ...  |
|       2 |          1 | Discharge | blah ...  |
|       3 |          1 | Nursing   | blah ...  |
|       4 |          2 | Nursing   | blah ...  |
|       5 |          2 | Nursing   | blah ...  |
|       6 |          3 | ECG       | blah ...  |

There are multiple categories - which are not evenly balanced - so I need to ensure that the training, validation and test sets all have the same proportions of categories as in the original dataset. This part is fine, I can just use StratifiedShuffleSplit from the sklearn library.

However, I also need to ensure that the observations from each subject are not split across the training, validation and test datasets. All the observations from a given subject need to be in the same bucket to ensure my trained model has never seen the subject before when it comes to validation/testing. E.g. every observation of subject_id 1 should be in the training set.

I can't think of a way to ensure a stratified split by category, prevent contamination (for want of a better word) of subject_id across datasets, ensure a 60:20:20 split and ensure that the dataset is somehow shuffled. Any help would be appreciated!



I've now learnt that grouping by a category and keeping groups together across dataset splits can also be accomplished by sklearn through the GroupShuffleSplit function. So essentially, what I need is a combined stratified and grouped shuffle split i.e. StratifiedGroupShuffleSplit which does not exist. Github issue: https://github.com/scikit-learn/scikit-learn/issues/12076


Essentially I need StratifiedGroupShuffleSplit which does not exist (Github issue). This is because the behaviour of such a function is unclear and accomplishing this to yield a dataset which is both grouped and stratified is not always possible (also discussed here) - especially with a heavily imbalanced dataset such as mine. In my case, I want grouping to be done strictly to ensure there is no overlap of groups whatsoever whilst stratification and the dataset ratio split of 60:20:20 to be done approximately i.e. as well as is possible.

As Ghanem mentions, I have no choice but to build a function to split the dataset myself, which I have done below:

def StratifiedGroupShuffleSplit(df_main):

    df_main = df_main.reindex(np.random.permutation(df_main.index)) # shuffle dataset

    # create empty train, val and test datasets
    df_train = pd.DataFrame()
    df_val = pd.DataFrame()
    df_test = pd.DataFrame()

    hparam_mse_wgt = 0.1 # must be between 0 and 1
    assert(0 <= hparam_mse_wgt <= 1)
    train_proportion = 0.6 # must be between 0 and 1
    assert(0 <= train_proportion <= 1)
    val_test_proportion = (1-train_proportion)/2

    subject_grouped_df_main = df_main.groupby(['subject_id'], sort=False, as_index=False)
    category_grouped_df_main = df_main.groupby('category').count()[['subject_id']]/len(df_main)*100

    def calc_mse_loss(df):
        grouped_df = df.groupby('category').count()[['subject_id']]/len(df)*100
        df_temp = category_grouped_df_main.join(grouped_df, on = 'category', how = 'left', lsuffix = '_main')
        df_temp.fillna(0, inplace=True)
        df_temp['diff'] = (df_temp['subject_id_main'] - df_temp['subject_id'])**2
        mse_loss = np.mean(df_temp['diff'])
        return mse_loss

    i = 0
    for _, group in subject_grouped_df_main:

        if (i < 3):
            if (i == 0):
                df_train = df_train.append(pd.DataFrame(group), ignore_index=True)
                i += 1
            elif (i == 1):
                df_val = df_val.append(pd.DataFrame(group), ignore_index=True)
                i += 1
                df_test = df_test.append(pd.DataFrame(group), ignore_index=True)
                i += 1

        mse_loss_diff_train = calc_mse_loss(df_train) - calc_mse_loss(df_train.append(pd.DataFrame(group), ignore_index=True))
        mse_loss_diff_val = calc_mse_loss(df_val) - calc_mse_loss(df_val.append(pd.DataFrame(group), ignore_index=True))
        mse_loss_diff_test = calc_mse_loss(df_test) - calc_mse_loss(df_test.append(pd.DataFrame(group), ignore_index=True))

        total_records = len(df_train) + len(df_val) + len(df_test)

        len_diff_train = (train_proportion - (len(df_train)/total_records))
        len_diff_val = (val_test_proportion - (len(df_val)/total_records))
        len_diff_test = (val_test_proportion - (len(df_test)/total_records)) 

        len_loss_diff_train = len_diff_train * abs(len_diff_train)
        len_loss_diff_val = len_diff_val * abs(len_diff_val)
        len_loss_diff_test = len_diff_test * abs(len_diff_test)

        loss_train = (hparam_mse_wgt * mse_loss_diff_train) + ((1-hparam_mse_wgt) * len_loss_diff_train)
        loss_val = (hparam_mse_wgt * mse_loss_diff_val) + ((1-hparam_mse_wgt) * len_loss_diff_val)
        loss_test = (hparam_mse_wgt * mse_loss_diff_test) + ((1-hparam_mse_wgt) * len_loss_diff_test)

        if (max(loss_train,loss_val,loss_test) == loss_train):
            df_train = df_train.append(pd.DataFrame(group), ignore_index=True)
        elif (max(loss_train,loss_val,loss_test) == loss_val):
            df_val = df_val.append(pd.DataFrame(group), ignore_index=True)
            df_test = df_test.append(pd.DataFrame(group), ignore_index=True)

        print ("Group " + str(i) + ". loss_train: " + str(loss_train) + " | " + "loss_val: " + str(loss_val) + " | " + "loss_test: " + str(loss_test) + " | ")
        i += 1

    return df_train, df_val, df_test

df_train, df_val, df_test = StratifiedGroupShuffleSplit(df_main)

I have created some arbitrary loss function based on 2 things:

  1. The average squared difference in the percentage representation of each category compared to the overall dataset
  2. The squared difference between the proportional length of the dataset compared to what it should be according to the ratio supplied (60:20:20)

Weighting these two inputs to the loss function is done by the static hyperparameter hparam_mse_wgt. For my particular dataset, a value of 0.1 worked well but I would encourage you to play around with it if you use this function. Setting it to 0 will prioritise only maintaining the split ratio and ignore the stratification. Setting it to 1 would be vice versa.

Using this loss function, I then iterate through each subject (group) and append it to the appropriate dataset (training, validation or test) according to whichever has the highest loss function.

It's not particularly complicated but it does the job for me. It won't necessarily work for every dataset, but the larger it is, the better the chance. Hopefully someone else will find it useful.


I just had to solve the same problem. In my document processing use case I wanted words from the same page to stick together (group), while document categories should be split across the train and test set evenly (stratify). For my problem it holds that for all instances of one group we have the same stratification category, i.e. all words from one page belong to the same category. Therefore, I found it easiest to perform the stratified split on the groups directly and then to use the split groups to select the instances. Where this assumption does not hold, this solution is not applicable though.

from typing import Tuple

import pandas as pd
from sklearn.model_selection import train_test_split

def stratified_group_train_test_split(
    samples: pd.DataFrame, group: str, stratify_by: str, test_size: float
) -> Tuple[pd.DataFrame, pd.DataFrame]:
    groups = samples[group].drop_duplicates()
    stratify = samples.drop_duplicates(group)[stratify_by].to_numpy()
    groups_train, groups_test = train_test_split(groups, stratify=stratify, test_size=test_size)

    samples_train = samples.loc[lambda d: d[group].isin(groups_train)]
    samples_test = samples.loc[lambda d: d[group].isin(groups_test)]

    return samples_train, samples_test

I think in this case you have to build your own function to split the data. This is an implementation by me:

def split(df, based_on='subject_id', cv=5):
    splits = []
    based_on_uniq = df[based_on]#set(df[based_on].tolist())
    based_on_uniq = np.array_split(based_on_uniq, cv)
    for fold in based_on_uniq:
        splits.append(df[df[based_on] == fold.tolist()[0]])
    return splits

if __name__ == '__main__':
    df = pd.DataFrame([{'note_id': 1, 'subject_id': 1, 'category': 'test1', 'note': 'test1'},
                       {'note_id': 2, 'subject_id': 1, 'category': 'test2', 'note': 'test2'},
                       {'note_id': 3, 'subject_id': 2, 'category': 'test3', 'note': 'test3'},
                       {'note_id': 4, 'subject_id': 2, 'category': 'test4', 'note': 'test4'},
                       {'note_id': 5, 'subject_id': 3, 'category': 'test5', 'note': 'test5'},
                       {'note_id': 6, 'subject_id': 3, 'category': 'test6', 'note': 'test6'},
                       {'note_id': 7, 'subject_id': 4, 'category': 'test7', 'note': 'test7'},
                       {'note_id': 8, 'subject_id': 4, 'category': 'test8', 'note': 'test8'},
                       {'note_id': 9, 'subject_id': 5, 'category': 'test9', 'note': 'test9'},
                       {'note_id': 10, 'subject_id': 5, 'category': 'test10', 'note': 'test10'},
  • I think you're probably right. Thanks for the starter code for returning split points. I guess the question is how much of it can be made easier by using library-provided functions. I'll see what I can come up with – amin_nejad Jul 3 '19 at 15:51

this got more than a year, but i found my self in a similare situation where i have labels and a groups, and due to the nature of the groups one group of data points can be either in test only or in train only, i've wrote this a small algo using pandas and sklearn i hope this would help

from sklearn.model_selection import GroupShuffleSplit
groups = df.groupby('label')
all_train = []
all_test = []
for group_id, group in groups:
    # if a group is already taken in test or train it must stay there
    group = group[~group['groups'].isin(all_train+all_test)]
    # if group is empty 
    if group.shape[0] == 0:
    train_inds, test_inds = next(GroupShuffleSplit(
        test_size=valid_size, n_splits=2, random_state=7).split(group, groups=group['groups']))

    all_train += group.iloc[train_inds]['groups'].tolist()
    all_test += group.iloc[test_inds]['groups'].tolist()

train= df[df['groups'].isin(all_train)]
test= df[df['groups'].isin(all_test)]

form_train = set(train['groups'].tolist())
form_test = set(test['groups'].tolist())
inter = form_train.intersection(form_test)

print(inter) # this should be empty

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