# How to split data into 3 sets (train, validation and test)?

I have a pandas dataframe and I wish to divide it to 3 separate sets. I know that using train_test_split from `sklearn.cross_validation`, one can divide the data in two sets (train and test). However, I couldn't find any solution about splitting the data into three sets. Preferably, I'd like to have the indices of the original data.

I know that a workaround would be to use `train_test_split` two times and somehow adjust the indices. But is there a more standard / built-in way to split the data into 3 sets instead of 2?

• This doesn't answer your specific question, but I think the more standard approach for this would be splitting into two sets, train and test, and running cross-validation on the training set thus eliminating the need for a stand alone "development" set. Jul 7, 2016 at 16:40
• This came up before, and as far as I know there is no built-in method for that yet. Jul 7, 2016 at 16:43
• I suggest Hastie et al.'s The Elements of Statistical Learning for a discussion on why to use three sets instead of two (web.stanford.edu/~hastie/local.ftp/Springer/OLD/… Model assessment and selection chapter) Jul 7, 2016 at 17:16
• @David In some models to prevent overfitting, there is a need for 3 sets instead of 2. Because in your design choices, you are somehow tuning parameters to improve performance on the test set. To prevent that, a development set is required. So, using cross validation will not be sufficient. Jul 7, 2016 at 17:23
• @ayhan, a corrected URL for that book is statweb.stanford.edu/~tibs/ElemStatLearn/printings/…, chapter 7 (p. 219). May 8, 2017 at 19:50

Numpy solution. We will shuffle the whole dataset first (`df.sample(frac=1, random_state=42)`) and then split our data set into the following parts:

• 60% - train set,
• 20% - validation set,
• 20% - test set

``````In : train, validate, test = \
np.split(df.sample(frac=1, random_state=42),
[int(.6*len(df)), int(.8*len(df))])

In : train
Out:
A         B         C         D         E
0  0.046919  0.792216  0.206294  0.440346  0.038960
2  0.301010  0.625697  0.604724  0.936968  0.870064
1  0.642237  0.690403  0.813658  0.525379  0.396053
9  0.488484  0.389640  0.599637  0.122919  0.106505
8  0.842717  0.793315  0.554084  0.100361  0.367465
7  0.185214  0.603661  0.217677  0.281780  0.938540

In : validate
Out:
A         B         C         D         E
5  0.806176  0.008896  0.362878  0.058903  0.026328
6  0.145777  0.485765  0.589272  0.806329  0.703479

In : test
Out:
A         B         C         D         E
4  0.521640  0.332210  0.370177  0.859169  0.401087
3  0.333348  0.964011  0.083498  0.670386  0.169619
``````

`[int(.6*len(df)), int(.8*len(df))]` - is an `indices_or_sections ` array for numpy.split().

Here is a small demo for `np.split()` usage - let's split 20-elements array into the following parts: 80%, 10%, 10%:

``````In : a = np.arange(1, 21)

In : a
Out: array([ 1,  2,  3,  4,  5,  6,  7,  8,  9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20])

In : np.split(a, [int(.8 * len(a)), int(.9 * len(a))])
Out:
[array([ 1,  2,  3,  4,  5,  6,  7,  8,  9, 10, 11, 12, 13, 14, 15, 16]),
array([17, 18]),
array([19, 20])]
``````
• @root what exactly is the frac=1 parameter doing? Mar 12, 2017 at 2:52
• @SpiderWasp42, `frac=1` instructs `sample()` function to return all (`100%` or fraction = `1.0`) rows Mar 12, 2017 at 8:45
• Thanks @MaxU. I'd like to mention 2 things to keep things simplified. First, use `np.random.seed(any_number)` before the split line to obtain same result with every run. Second, to make unequal ratio like `train:test:val::50:40:10` use `[int(.5*len(dfn)), int(.9*len(dfn))]`. Here first element denotes size for `train` (0.5%), second element denotes size for `val` (1-0.9 = 0.1%) and difference between the two denotes size for `test`(0.9-0.5 = 0.4%). Correct me if I'm wrong :) May 7, 2018 at 17:57
• hrmm is it a mistake when you say "Here is a small demo for np.split() usage - let's split 20-elements array into the following parts: 90%, 10%, 10%:" I am pretty sure you mean 80%, 10%, 10% Jan 11, 2019 at 21:19
• Hey, @MaxU I had a case, something somewhat similar. I was wondering if you could look at it for me to see if it is and help me there. Here is my question stackoverflow.com/questions/54847668/… Feb 24, 2019 at 2:17

However, one approach to dividing the dataset into `train`, `test`, `cv` with `0.6`, `0.2`, `0.2` would be to use the `train_test_split` method twice.

``````from sklearn.model_selection import train_test_split

x, x_test, y, y_test = train_test_split(xtrain,labels,test_size=0.2,train_size=0.8)
x_train, x_cv, y_train, y_cv = train_test_split(x,y,test_size = 0.25,train_size =0.75)
``````
• @MaksymGanenko Can you please elaborate ? Sep 1, 2019 at 6:43
• With `np.split()` you can split indices and so you may reindex any datatype. If you look into `train_test_split()` you'll see that it does exactly the same way: define `np.arange()`, shuffle it and then reindex original data. But `train_test_split()` can't split data into three datasets, so its use is limited. In the context of the answer it's suboptimal (== wrong). Sep 2, 2019 at 9:56
• another benefit of this approach is that you can use the stratification parameters. Mar 24, 2020 at 9:57
• A simple and easy enough approach! Aug 18, 2020 at 7:00
• @MaksymGanenko: Who cares if its performance is suboptimal? Typically, you'd want to perform train/val/test splitting only once, so therefore you want to make sure it's done correctly, not just efficiently. For train/val/test splitting, you need to have stratified sampling, which is not available with Numpy `split()`; you have to implement stratification yourself. The sci-kit learn function does all that for you using `train_test_split()`. Jan 4, 2021 at 23:42

### Note:

Function was written to handle seeding of randomized set creation. You should not rely on set splitting that doesn't randomize the sets.

``````import numpy as np
import pandas as pd

def train_validate_test_split(df, train_percent=.6, validate_percent=.2, seed=None):
np.random.seed(seed)
perm = np.random.permutation(df.index)
m = len(df.index)
train_end = int(train_percent * m)
validate_end = int(validate_percent * m) + train_end
train = df.iloc[perm[:train_end]]
validate = df.iloc[perm[train_end:validate_end]]
test = df.iloc[perm[validate_end:]]
return train, validate, test
``````

### Demonstration

``````np.random.seed([3,1415])
df = pd.DataFrame(np.random.rand(10, 5), columns=list('ABCDE'))
df
`````` ``````train, validate, test = train_validate_test_split(df)

train
`````` ``````validate
`````` ``````test
`````` • I believe this function requires a df with index values ranging from 1 to n. In my case, I modified the function to use df.loc as my index values were not necessarily in this range. Apr 16, 2020 at 12:38

Here is a Python function that splits a Pandas dataframe into train, validation, and test dataframes with stratified sampling. It performs this split by calling scikit-learn's function `train_test_split()` twice.

``````import pandas as pd
from sklearn.model_selection import train_test_split

def split_stratified_into_train_val_test(df_input, stratify_colname='y',
frac_train=0.6, frac_val=0.15, frac_test=0.25,
random_state=None):
'''
Splits a Pandas dataframe into three subsets (train, val, and test)
following fractional ratios provided by the user, where each subset is
stratified by the values in a specific column (that is, each subset has
the same relative frequency of the values in the column). It performs this
splitting by running train_test_split() twice.

Parameters
----------
df_input : Pandas dataframe
Input dataframe to be split.
stratify_colname : str
The name of the column that will be used for stratification. Usually
this column would be for the label.
frac_train : float
frac_val   : float
frac_test  : float
The ratios with which the dataframe will be split into train, val, and
test data. The values should be expressed as float fractions and should
sum to 1.0.
random_state : int, None, or RandomStateInstance
Value to be passed to train_test_split().

Returns
-------
df_train, df_val, df_test :
Dataframes containing the three splits.
'''

if frac_train + frac_val + frac_test != 1.0:
raise ValueError('fractions %f, %f, %f do not add up to 1.0' % \
(frac_train, frac_val, frac_test))

if stratify_colname not in df_input.columns:
raise ValueError('%s is not a column in the dataframe' % (stratify_colname))

X = df_input # Contains all columns.
y = df_input[[stratify_colname]] # Dataframe of just the column on which to stratify.

# Split original dataframe into train and temp dataframes.
df_train, df_temp, y_train, y_temp = train_test_split(X,
y,
stratify=y,
test_size=(1.0 - frac_train),
random_state=random_state)

# Split the temp dataframe into val and test dataframes.
relative_frac_test = frac_test / (frac_val + frac_test)
df_val, df_test, y_val, y_test = train_test_split(df_temp,
y_temp,
stratify=y_temp,
test_size=relative_frac_test,
random_state=random_state)

assert len(df_input) == len(df_train) + len(df_val) + len(df_test)

return df_train, df_val, df_test
``````

Below is a complete working example.

Consider a dataset that has a label upon which you want to perform the stratification. This label has its own distribution in the original dataset, say 75% `foo`, 15% `bar` and 10% `baz`. Now let's split the dataset into train, validation, and test into subsets using a 60/20/20 ratio, where each split retains the same distribution of the labels. See the illustration below: Here is the example dataset:

``````df = pd.DataFrame( { 'A': list(range(0, 100)),
'B': list(range(100, 0, -1)),
'label': ['foo'] * 75 + ['bar'] * 15 + ['baz'] * 10 } )

#    A    B label
# 0  0  100   foo
# 1  1   99   foo
# 2  2   98   foo
# 3  3   97   foo
# 4  4   96   foo

df.shape
# (100, 3)

df.label.value_counts()
# foo    75
# bar    15
# baz    10
# Name: label, dtype: int64
``````

Now, let's call the `split_stratified_into_train_val_test()` function from above to get train, validation, and test dataframes following a 60/20/20 ratio.

``````df_train, df_val, df_test = \
split_stratified_into_train_val_test(df, stratify_colname='label', frac_train=0.60, frac_val=0.20, frac_test=0.20)
``````

The three dataframes `df_train`, `df_val`, and `df_test` contain all the original rows but their sizes will follow the above ratio.

``````df_train.shape
#(60, 3)

df_val.shape
#(20, 3)

df_test.shape
#(20, 3)
``````

Further, each of the three splits will have the same distribution of the label, namely 75% `foo`, 15% `bar` and 10% `baz`.

``````df_train.label.value_counts()
# foo    45
# bar     9
# baz     6
# Name: label, dtype: int64

df_val.label.value_counts()
# foo    15
# bar     3
# baz     2
# Name: label, dtype: int64

df_test.label.value_counts()
# foo    15
# bar     3
# baz     2
# Name: label, dtype: int64
``````
• NameError: name 'df' is not defined. The 'df' in split_stratified_into_train_val_test() should be replaced with 'df_input'. May 18, 2020 at 11:24
• Thanks. I fixed it. The problem was in an error-handling path of the code. May 18, 2020 at 18:09

In the case of supervised learning, you may want to split both X and y (where X is your input and y the ground truth output). You just have to pay attention to shuffle X and y the same way before splitting.

Here, either X and y are in the same dataframe, so we shuffle them, separate them and apply the split for each (just like in chosen answer), or X and y are in two different dataframes, so we shuffle X, reorder y the same way as the shuffled X and apply the split to each.

``````# 1st case: df contains X and y (where y is the "target" column of df)
df_shuffled = df.sample(frac=1)
X_shuffled = df_shuffled.drop("target", axis = 1)
y_shuffled = df_shuffled["target"]

# 2nd case: X and y are two separated dataframes
X_shuffled = X.sample(frac=1)
y_shuffled = y[X_shuffled.index]

# We do the split as in the chosen answer
X_train, X_validation, X_test = np.split(X_shuffled, [int(0.6*len(X)),int(0.8*len(X))])
y_train, y_validation, y_test = np.split(y_shuffled, [int(0.6*len(X)),int(0.8*len(X))])
``````

It is very convenient to use `train_test_split` without performing reindexing after dividing to several sets and not writing some additional code. Best answer above does not mention that by separating two times using `train_test_split` not changing partition sizes won`t give initially intended partition:

``````x_train, x_remain = train_test_split(x, test_size=(val_size + test_size))
``````

Then the portion of validation and test sets in the x_remain change and could be counted as

``````new_test_size = np.around(test_size / (val_size + test_size), 2)
# To preserve (new_test_size + new_val_size) = 1.0
new_val_size = 1.0 - new_test_size

x_val, x_test = train_test_split(x_remain, test_size=new_test_size)
``````

In this occasion all initial partitions are saved.

``````def train_val_test_split(X, y, train_size, val_size, test_size):
X_train_val, X_test, y_train_val, y_test = train_test_split(X, y, test_size = test_size)
relative_train_size = train_size / (val_size + train_size)
X_train, X_val, y_train, y_val = train_test_split(X_train_val, y_train_val,
train_size = relative_train_size, test_size = 1-relative_train_size)
return X_train, X_val, X_test, y_train, y_val, y_test
``````

Here we split data 2 times with sklearn's `train_test_split`

Considering that `df` id your original dataframe:

1 - First you split data between Train and Test (10%):

``````my_test_size = 0.10

X_train_, X_test, y_train_, y_test = train_test_split(
df.index.values,
df.label.values,
test_size=my_test_size,
random_state=42,
stratify=df.label.values,
)
``````

2 - Then you split the train set between train and validation (20%):

``````my_val_size = 0.20

X_train, X_val, y_train, y_val = train_test_split(
df.loc[X_train_].index.values,
df.loc[X_train_].label.values,
test_size=my_val_size,
random_state=42,
stratify=df.loc[X_train_].label.values,
)
``````

3 - Then, you slice the original dataframe according to the indices generated in the steps above:

``````# data_type is not necessary.
df['data_type'] = ['not_set']*df.shape
df.loc[X_train, 'data_type'] = 'train'
df.loc[X_val, 'data_type'] = 'val'
df.loc[X_test, 'data_type'] = 'test'
``````

The result is going to be like this: Note: This soluctions uses the workaround mentioned in the question.

ANSWER FOR ANY AMOUNT OF SUB-SETS:

``````def _separate_dataset(patches, label_patches, percentage, shuffle: bool = True):
"""
:param patches: data patches
:param label_patches: label patches
:param percentage: list of percentages for each value, example [0.9, 0.02, 0.08] to get 90% train, 2% val and 8% test.
:param shuffle: Shuffle dataset before split.
:return: tuple of two lists of size = len(percentage), one with data x and other with labels y.
"""
x_test = patches
y_test = label_patches
percentage = list(percentage)       # need it to be mutable
assert sum(percentage) == 1., f"percentage must add to 1, but it adds to sum{percentage} = {sum(percentage)}"
x = []
y = []
for i, per in enumerate(percentage[:-1]):
x_train, x_test, y_train, y_test = train_test_split(x_test, y_test, test_size=1-per, shuffle=shuffle)
percentage[i+1:] = [value / (1-percentage[i]) for value in percentage[i+1:]]
x.append(x_train)
y.append(y_train)
x.append(x_test)
y.append(y_test)
return x, y
``````

This work for any size of percentage. In your case, you should do `percentage = [train_percentage, val_percentage, test_percentage]`.

The easiest way that I could think of is mapping split fractions to array index as follows:

``````train_set = data[:int((len(data)+1)*train_fraction)]
test_set = data[int((len(data)+1)*train_fraction):int((len(data)+1)*(train_fraction+test_fraction))]
val_set = data[int((len(data)+1)*(train_fraction+test_fraction)):]
``````

where `data = random.shuffle(data)`

Split the dataset in training and testing set as in the other answers, using

``````from sklearn.model_selection import train_test_split

X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.2, random_state=42)
``````

Then, if you fit your model, you can add `validation_split` as a parameter. Then you do not need to create the validation set in advance. For example:

``````from tensorflow.keras import Model

model = Model(input_layer, out)

[...]

history = model.fit(x=X_train, y=y_train, [...], validation_split = 0.3)
``````

The validation set is meant to serve as a representative on-the-run-testing-set during training of the training set, taken entirely from the training set, be it by k-fold cross-validation (recommended) or by `validation_split`; then you do not need to create a validation set separately and still you split a dataset into the three sets you are asking for.