data science preprocessing toolkit and container
Project description
dstkc
data science toolkit and storage container
This toolkit is meant to be a storage container that organizes your data and data science models so that it is easy to work with. This class acts as both a pre-processor, as well as a storage container
:param df: Pandas dataframe for
:param model: data science model
:param y_col: column in df that contains dependent variable
:param x_cols: columns in df that contain independent variables
:param train_test_split_params: parameters for sci-kit learn's train test split function see https://scikit-learn.org/stable/modules/generated/sklearn.model_selection.train_test_split.html for reference
other attributes include:
:attr train_data - pandas dataframe with all training data
:attr test_data - pandas dataframe with all testing data
:attr x_data - pandas dataframe with all x data
:attr y_data - pandas dataframe with all y data
:attr x_test - pandas dataframe with all x testing data
:attr x_train - pandas dataframe with all x training data
:attr x_test_array - numpy array with all x testing data
:attr x_train_array - numpy array with all x training data
:attr y_test - pandas dataframe with all y testing data
:attr y_train - pandas dataframe with all y training data
:attr y_test_array - numpy array with all y testing data
:attr y_train_array - numpy array with all y training data
:attr model - store your model here for later use
:attr predictions - store your model's predictions here
:attr score - store a scoring or performance metric here
:attr notes - place for you to store any and all notes
:attr misc_container - dict style container for storing anything else you might need
here is an example of a few use cases
import pandas as pd
from operator import attrgetter
from sklearn.neighbors import KNeighborsClassifier
from sklearn.tree import DecisionTreeClassifier
from sklearn.ensemble import RandomForestClassifier
from sklearn.linear_model import SGDClassifier
from sklearn.naive_bayes import GaussianNB
from sklearn.metrics import confusion_matrix
from dstkc.tkc import DataScienceToolKit
def example_main():
# here we read in the iris data set (because it's a classic)
df = pd.read_csv(
"https://archive.ics.uci.edu/ml/machine-learning-databases/iris/iris.data",
names=[
'sepal_length',
'sepal_width',
'petal_length',
'petal_width',
'species'
]
)
# we need to handle a bit of data pre processing,
# currently the toolkit doesn't handle for nulls or string->numeric
df['species'] = df['species'].apply(
lambda x: 0 if x == 'Iris-setosa' else 1 if x == 'Iris-versicolor' else 2
)
# there are two useful cases for this toolkit as it stands, one is cycling through columns if you're unsure
# what combination of columns to use
all_x_cols = df.columns[:-1]
y_col = df.columns[-1:]
# here we are going to try different combinations of columns, and store the information. note
# how there is no mention of data processing other than our data cleaning with our dataframe
toolkit_storage_container = []
for i in range(1, len(all_x_cols)):
# not technically useful in this instance, but naming the model will be something to revisit in the future
model_name = 'knn'
x_cols = all_x_cols[i:]
# the class uses train test split from sklearn, the final argument are the parameters for the function call
# see: https://scikit-learn.org/stable/modules/generated/sklearn.model_selection.train_test_split.html for details
dstk = DataScienceToolKit(
df=df,
model=KNeighborsClassifier(),
y_col=y_col,
x_cols=x_cols,
train_test_split_params={
'test_size': 0.3
}
)
# each container can store notes, among other handy values, there is also a miscellaneous container
# which acts as a dictionary in case you want to have something else float around with all of your
# data and models
dstk.notes = model_name
# and just like that, you have all of your data ready to go, in one place!
print(dstk.x_train) # here is your data as a dataframe for inspection, debugging, etc.
print(dstk.x_train_array) # here is your dat as an array for your modeling
print(dstk.y_train) # here is your data as a dataframe for inspection, debugging, etc.
print(dstk.y_train_array) # here is your dat as an array for your modeling
print(dstk.x_test) # here is your data as a dataframe for inspection, debugging, etc.
print(dstk.x_test_array) # here is your dat as an array for your modeling
print(dstk.y_test) # here is your data as a dataframe for inspection, debugging, etc.
print(dstk.y_test_array) # here is your dat as an array for your modeling
# please note that we fit and score the model using the model's native features
# so we can use any model, this is not only for scikit learn
dstk.model.fit(dstk.x_train_array, dstk.y_train_array)
# we can also store the predictions and score of the model, in any fashion or form you would like
dstk.predictions = dstk.model.predict(dstk.x_test_array)
dstk.score = dstk.model.score(
dstk.x_test_array, dstk.y_test_array
)
# we're gonna store this for later, this is where the real use case comes in
toolkit_storage_container.append(dstk)
# now that we have finished iterating over a bunch of different column sets, maybe we want to know
# which had the best performance
best_dstk = max(toolkit_storage_container, key=attrgetter('score'))
# now we may want to know what the columns were, or inspect that dataset outside of our code
print(best_dstk.x_cols)
# best_dstk.train_data.to_csv('./train_data.csv')
# best_dstk.test_data.to_csv('./test_data.csv')
# most importantly, all of the data, along with the model, performance information,
# predictions, arrays, dataframes, and anything else are now sitting together, and you can
# use any feature of the model to inspect, or use any aspect of the work we have done, without
# altering any of your prior code
# another use case is comparing model performance, not just column set performance
# (now names/notes become more important)
model_dict = {
'sgdc': SGDClassifier(),
'gauss': GaussianNB(),
'knn': KNeighborsClassifier(),
'dtc': DecisionTreeClassifier(),
'rfc': RandomForestClassifier(),
}
# re-initializing this for new example
toolkit_storage_container = []
for key_, value_ in model_dict.items():
model_name = key_
new_model = value_
# note that in this instance, we are not declaring x cols, because we are going to
# use all columns other than the y_col, and that is default behaviour for the toolkit
# also, if the y col was in the first position of the dataframe, it would not have to be
# specified either
dstk = DataScienceToolKit(
df=df,
model=new_model,
y_col=y_col,
train_test_split_params={
'test_size': 0.3
}
)
dstk.notes = model_name
dstk.model.fit(
dstk.x_train_array, dstk.y_train_array
)
dstk.predictions = dstk.model.predict(
dstk.x_test_array
)
dstk.score = dstk.model.score(
dstk.x_test_array, dstk.y_test_array
)
# here is an example of using the miscellaneous container to store a confusion matrix
# for later
dstk.misc_container['confusion_matrix'] = confusion_matrix(
dstk.y_test_array, dstk.predictions
)
toolkit_storage_container.append(dstk)
# this time around, we want to know which model had the best score
best_dstk = max(toolkit_storage_container, key=attrgetter('score'))
# and yet again, we have all of the relevant information, like which model was best, what the performance was
# we also have all the models, in case we want to test or compare any aspect of them
# further more, one can combine the two cases and iterate over column sets, and model choices
# to quickly hone in on interesting data points, without having to clean the data or split the data
# and store the data in any way that usually causes (well at least for me) any headaches
print(best_dstk.notes)
print(best_dstk.score)
print(best_dstk.misc_container['confusion_matrix'])
print(
'''
hope you enjoy, and find this useful!
'''
)
if __name__ == '__main__':
example_main()
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
