An Open Source Project from the Data to AI Lab, at MIT
Pipelines and primitives for machine learning and data science.
- Documentation: https://MLBazaar.github.io/MLPrimitives
- Github: https://github.com/MLBazaar/MLPrimitives
- License: MIT
- Development Status: Pre-Alpha
This repository contains primitive annotations to be used by the MLBlocks library, as well as the necessary Python code to make some of them fully compatible with the MLBlocks API requirements.
There is also a collection of custom primitives contributed directly to this library, which either combine third party tools or implement new functionalities from scratch.
- Too many libraries in a fast growing field
- Huge societal need to build machine learning apps
- Domain expertise resides at several places (knowledge of math)
- No documented information about hyperparameters, behavior...
MLPrimitives has been developed and tested on Python 3.8, 3.9, 3.10, and 3.11
Also, although it is not strictly required, the usage of a virtualenv is highly recommended in order to avoid interfering with other software installed in the system where MLPrimitives is run.
The easiest and recommended way to install MLPrimitives is using pip:
pip install mlprimitives
This will pull and install the latest stable release from PyPi.
If you want to install from source or contribute to the project please read the Contributing Guide.
This section is a short series of tutorials to help you getting started with MLPrimitives.
In the following steps you will learn how to load and run a primitive on some data.
Later on you will learn how to evaluate and improve the performance of a primitive by tuning its hyperparameters.
In this first tutorial, we will be executing a single primitive for data transformation.
The first step in order to run a primitive is to load it.
This will be done using the mlprimitives.load_primitive
function, which will
load the indicated primitive as an MLBlock Object from MLBlocks
In this case, we will load the mlprimitives.custom.feature_extraction.CategoricalEncoder
primitive.
from mlprimitives import load_primitive
primitive = load_primitive('mlprimitives.custom.feature_extraction.CategoricalEncoder')
The CategoricalEncoder is a transformation primitive which applies one-hot encoding to all the
categorical columns of a pandas.DataFrame
.
So, in order to be able to run our primitive, we will first load some data that contains categorical columns.
This can be done with the mlprimitives.datasets.load_census
function:
from mlprimitives.datasets import load_census
dataset = load_census()
This dataset object has an attribute data
which contains a table with several categorical
columns.
We can have a look at this table by executing dataset.data.head()
, which will return a
table like this:
0 1 2
age 39 50 38
workclass State-gov Self-emp-not-inc Private
fnlwgt 77516 83311 215646
education Bachelors Bachelors HS-grad
education-num 13 13 9
marital-status Never-married Married-civ-spouse Divorced
occupation Adm-clerical Exec-managerial Handlers-cleaners
relationship Not-in-family Husband Not-in-family
race White White White
sex Male Male Male
capital-gain 2174 0 0
capital-loss 0 0 0
hours-per-week 40 13 40
native-country United-States United-States United-States
In order to run our pipeline, we first need to fit it.
This is the process where it analyzes the data to detect which columns are categorical
This is done by calling its fit
method and assing the dataset.data
as X
.
primitive.fit(X=dataset.data)
Once the pipeline is fit, we can process the data by calling the produce
method of the
primitive instance and passing agin the data
as X
.
transformed = primitive.produce(X=dataset.data)
After this is done, we can see how the transformed data contains the newly generated one-hot vectors:
0 1 2 3 4
age 39 50 38 53 28
fnlwgt 77516 83311 215646 234721 338409
education-num 13 13 9 7 13
capital-gain 2174 0 0 0 0
capital-loss 0 0 0 0 0
hours-per-week 40 13 40 40 40
workclass= Private 0 0 1 1 1
workclass= Self-emp-not-inc 0 1 0 0 0
workclass= Local-gov 0 0 0 0 0
workclass= ? 0 0 0 0 0
workclass= State-gov 1 0 0 0 0
workclass= Self-emp-inc 0 0 0 0 0
... ... ... ... ... ...
In this short tutorial we will teach you how to evaluate the performance of a primitive and improve its performance by modifying its hyperparameters.
To do so, we will load a primitive that can learn from the transformed data that we just generated and later on make predictions based on new data.
Firs of all, we will load the xgboost.XGBClassifier
primitive that we will use afterwards.
primitive = load_primitive('xgboost.XGBClassifier')
Before being able to evaluate the primitive perfomance, we need to split the data in two parts: train, which will be used for the primitive to learn, and test, which will be used to make the predictions that later on will be evaluated.
In order to do this, we will get the first 75% of rows from the transformed data that we
obtained above and call it X_train
, and then set the next 25% of rows as X_test
.
train_size = int(len(transformed) * 0.75)
X_train = transformed.iloc[:train_size]
X_test = transformed.iloc[train_size:]
Similarly, we need to obtain the y_train
and y_test
variables containing the corresponding
output values.
y_train = dataset.target[:train_size]
y_test = dataset.target[train_size:]
Once we have have splitted the data, we can fit the primitive by passing X_train
and y_train
to its fit
method.
primitive.fit(X=X_train, y=y_train)
Once the primitive has been fitted, we can produce predictions using the X_test
data as input.
predictions = primitive.produce(X=X_test)
We can now evaluate how good the predictions from our primitive are by using the score
method from the dataset
object on both the expected output and the real output from the
primitive:
dataset.score(y_test, predictions)
This will output a float value between 0 and 1 indicating how good the predicitons are, being 0 the worst score possible and 1 the best one.
In this case we will obtain a score around 0.866
In order to improve the performance of our primitive we will try to modify a couple of its hyperparameters.
First we will see which hyperparameter values the primitive has by calling its
get_hyperparameters
method.
primitive.get_hyperparameters()
which will return a dictionary like this:
{
"n_jobs": -1,
"n_estimators": 100,
"max_depth": 3,
"learning_rate": 0.1,
"gamma": 0,
"min_child_weight": 1
}
Next, we will see which are the valid values for each one of those hyperparameters by calling its
get_tunable_hyperparameters
method:
primitive.get_tunable_hyperparameters()
For example, we will see that the max_depth
hyperparameter has the following specification:
{
"type": "int",
"default": 3,
"range": [
3,
10
]
}
Next, we will choose a valid value, for example 7, and set it into the pipeline using the
set_hyperparameters
method:
primitive.set_hyperparameters({'max_depth': 7})
Once the new hyperparameter value has been set, we repeat the fit/train/score cycle to evaluate the performance of this new hyperparameter value:
primitive.fit(X=X_train, y=y_train)
predictions = primitive.produce(X=X_test)
dataset.score(y_test, predictions)
This time we should see that the performance has improved to a value around 0.724
Do you want to learn more about how the project, about how to contribute to it or browse the API Reference? Please check the corresponding sections of the documentation!